CN116456652B - Electronic countermeasure in-situ detection equipment based on neural network - Google Patents

Abstract

The application discloses electronic countermeasure in-situ detection equipment based on a neural network, which comprises a detection equipment host, a module installation frame and a movable storage assembly, wherein a plug track frame is movably installed on the module installation frame, a first cable is installed in the module installation frame, connection interfaces are arranged on the module installation frame and the plug track frame, a second cable is arranged between the connection interfaces, the second cable penetrates through the movable storage assembly and extends to the outside of the movable storage assembly to be in a tight state, the movable storage assembly drives part of the second cable to move out of the movable storage assembly and drives part of the second cable to be pulled into the movable storage assembly according to the movement displacement of the plug track frame, and a push-pull structure is arranged on each plug track frame and pushes the plug track frame to slide so as to adjust the interval between adjacent plug track frames. According to the application, the heat dissipation gap between the adjacent detection processing modules is adjusted, so that the heat dissipation performance is improved.

Description

Electronic countermeasure in-situ detection equipment based on neural network

Technical Field

The application relates to the technical field of electronic in-situ countermeasure monitoring equipment, in particular to electronic in-situ countermeasure monitoring equipment based on a neural network.

Background

Modern warfare is an informationized warfare under high technical conditions, electronic countermeasure has become an important factor for determining the success or failure of future warfare, along with the wide application of high and new technologies, electronic countermeasure equipment is more and more complex, when the equipment has the problem of reduced combat performance or fails, the equipment is required to be timely removed from the failure, and normal performance of the equipment is recovered, so that in-situ detection equipment of an electronic countermeasure system is required to be used, and comprehensive guarantee means are provided for equipment index test and replacement maintenance.

In order to meet the use requirements of the guarantee equipment in the complex external field climate environment, the external field erection and the expansion of a plurality of test items are fully considered, the physical composition is divided, the electronic countermeasure system in-situ detection equipment mainly comprises a detection equipment host (comprising a radiation detector), a remote control terminal, auxiliary equipment (comprising an antenna assembly, a bracket, a charger and a cable) and the like, a plurality of detection modules are arranged in the detection equipment host, a pluggable board is usually arranged in the detection equipment host, each module is designed into a pluggable structural form, and input and output interfaces among the modules are connected through internal circuits or cables of the pluggable board.

The modules in the detection equipment host are tightly connected, gaps among the modules are small, heat dissipation performance is poor, and the positions among the modules cannot be adjusted due to the fixing effect of the pluggable plate and the cable pulling effect, so that the heat dissipation effect of the modules is uneven.

Disclosure of Invention

Therefore, the application provides electronic countermeasure in-situ detection equipment based on a neural network, which effectively solves the problems of the prior art that the modules in the detection equipment host are tightly connected, gaps among the modules are smaller, the heat dissipation performance is poorer, and the heat dissipation effect of the modules is uneven due to the fixing effect of a pluggable plate and the traction effect of a cable and the incapability of adjusting the positions among the modules.

In order to solve the technical problems, the application specifically provides the following technical scheme: an electronic countermeasure in-situ test apparatus based on a neural network includes:

the detection equipment host is internally provided with a detection processing module and a power supply module;

the module installation frame is arranged in the detection equipment host, a plug track frame is movably installed on the module installation frame, a first cable is installed in the module installation frame, the detection processing module is installed on the plug track frame, the power module is installed on one side, far away from the plug track frame, of the module installation frame, the power module is connected with the inside of the module installation frame through the first cable, connection interfaces are arranged on the module installation frame and the plug track frame, and a second cable is arranged between the connection interfaces;

the movable storage assembly is arranged between the connecting interfaces, the second cable passes through the movable storage assembly, the second cable extending out of the movable storage assembly is in a tight state, the movable storage assembly is movably arranged on the module mounting frame, and the movable storage assembly drives part of the second cable to move out of the movable storage assembly and drives part of the second cable to be pulled into the movable storage assembly according to the movement displacement of the plug track frame;

every interval is provided with a pushing structure on the plug track frame, the end part of the pushing structure is abutted with the adjacent plug track frame, and the pushing structure pushes the plug track frame to slide so as to adjust the interval between the adjacent plug track frames.

Further, a first sliding groove is formed in the module mounting frame, a sliding strip is mounted on the plug track frame, and the sliding strip is arranged in the first sliding groove in a sliding mode;

the detection processing module comprises a main controller, an intermediate frequency signal processing module, an up-down conversion module, a millimeter wave radio frequency module, a radiation detector and a video analysis module.

Further, the movable storage component comprises a movable barrel, a movable shaft column arranged in the movable barrel, a thread groove arranged on the movable shaft column and a thread line arranged in the movable barrel;

the movable cylinder is arranged in the first sliding groove, the thread lines are matched with the thread grooves, the side edges of the thread lines are in butt joint with the inner side walls of the thread grooves, thread storage grooves are formed between the thread lines and the thread grooves, and the second cables are distributed in the thread storage grooves.

Further, a connecting cylinder is further arranged on the side edge of the movable cylinder, the connecting cylinder is connected with the side wall of the movable cylinder through a connecting plate, the connecting cylinder and the movable cylinder are coaxially arranged, a bottom plate is arranged in the connecting cylinder, and a through hole for the second cable to pass through is formed in the bottom plate;

the bottom plate is provided with a threaded bottom column, the threaded bottom column is connected with a gear cylinder in a threaded mode, the gear cylinder is sleeved outside the threaded bottom column, and the end portion of the gear cylinder is connected with the movable shaft column.

Further, the movable cylinder and the connecting cylinder are externally provided with a driving cabin, a first driving motor is arranged in the driving cabin, the output end of the first driving motor is connected with a gear column, the side wall of the connecting cylinder is provided with a through groove, the side edge of the gear column penetrates through the through groove, and the side edge of the gear column is meshed with the gear cylinder.

Further, a sliding block is arranged on the movable cylinder, the sliding block is arranged in the first sliding groove in a sliding mode, racks are arranged on the side edges of the sliding block, a connecting cavity is arranged in the module mounting frame, and the connecting cavity is communicated with the first sliding groove;

the connecting cavity is internally provided with a connecting gear, the connecting gear is connected with a second driving motor, the connecting gear is connected with the output end of the second driving motor, and the rack is meshed with the connecting gear.

Further, the plug track frame consists of a sliding track wall and a mounting side wall, wherein the mounting side wall is vertically arranged on the side edge of the sliding track wall, and the sliding track wall is arranged on the module mounting frame in a sliding manner;

the side wall inner side of the installation side wall is provided with a sliding rail, the main controller, the intermediate frequency signal processing module, the up-down frequency conversion module, the millimeter wave radio frequency module, the radiation detector, the video analysis module bottom and the top are all provided with movable strips, and the movable strips are arranged in the sliding rail in a sliding manner.

Further, the compression structure comprises a driving cylinder penetrating through the sliding track wall, a threaded cylinder arranged in the driving cylinder, threaded rods arranged in two end parts of the threaded cylinder and abutting columns arranged at the end parts of the threaded rods;

the outer wall of the threaded cylinder is provided with an annular rack, a driving gear is arranged in the driving cylinder and meshed with the annular rack, a third driving motor is arranged on the driving gear, and the driving gear is connected to the output end of the third driving motor.

Further, an elongated slot is formed in the abutting column, a limit bolt is fixedly arranged at the opening of the driving cylinder, the end part of the limit bolt is arranged in the elongated slot, and the limit bolt is matched with the elongated slot.

Further, plug interfaces are arranged on the sliding track wall and on the side edges of the connection interfaces, and plug connectors are correspondingly plugged on the plug interfaces, wherein the main controller is provided with the intermediate frequency signal processing module, the up-down conversion module, the millimeter wave radio frequency module, the radiation detector and the video analysis module.

Compared with the prior art, the application has the following beneficial effects:

according to the application, the module mounting frame is arranged in the detection equipment host, the module mounting frame is movably provided with the pluggable track frames, the main controller, the intermediate frequency signal processing module, the up-down frequency conversion module, the millimeter wave radio frequency module, the radiation detector and the video analysis module are arranged on the pluggable track frames, wherein each interval one pluggable track frame is provided with the push-down structure, the push-down structure pushes the pluggable track frames to slide so as to adjust the interval between the adjacent pluggable track frames, adjust the heat dissipation gap between the adjacent detection processing modules, and improve the heat dissipation performance.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It will be apparent to those of ordinary skill in the art that the drawings in the following description are exemplary only and that other implementations can be obtained from the extensions of the drawings provided without inventive effort.

Fig. 1 is a schematic structural diagram of an electronic countermeasure in-situ detection device based on a neural network according to an embodiment of the present application;

FIG. 2 is a schematic view of a movable housing assembly according to an embodiment of the present application;

FIG. 3 is a schematic view of a movable barrel and a movable post according to an embodiment of the present application;

FIG. 4 is a schematic view of a movable shaft column according to an embodiment of the present application;

FIG. 5 is a schematic cross-sectional view of a movable housing assembly according to an embodiment of the present application;

FIG. 6 is a schematic view of the bottom structure of a connecting cylinder according to an embodiment of the present application;

FIG. 7 is a schematic cross-sectional view of a host computer of a detection apparatus according to an embodiment of the present application;

FIG. 8 is a schematic diagram of a push structure according to an embodiment of the present application;

fig. 9 is a block diagram of an electronic countermeasure in-situ detection apparatus based on a neural network according to an embodiment of the present application.

Reference numerals in the drawings are respectively as follows:

1-detecting a device host; 2-module mounting rack; 3-a movable storage assembly; 4-a detection processing module; a 5-power module; 6-inserting and pulling the track frame; 7-a first cable; 8-a push-pull structure; 9-a connection interface; 10-a second cable; 11-a first chute; 12-slide bar; 13-a plug interface; 14-plug;

31-a movable cylinder; 32-a movable shaft column; 33-thread groove; 34-thread line; 35-a thread receiving groove; 36-connecting a cylinder; 37-connecting plates; 38-a bottom plate; 39-perforating; 310-threaded bottom post; 311-gear cylinder; 312-a drive bay; 313-a first drive motor; 314-a gear post; 315-trough penetration; 316-slider; 317-rack; 318-connecting the chambers; 319-connecting gears; 320-a second drive motor;

61-sliding track walls; 62-mounting side walls; 63-sliding rails; 64-activity bars;

81-driving a cylinder; 82-a threaded cylinder; 83-a threaded rod; 84-abutting the column; 85-annular racks; 86-drive gear; 87-a third drive motor; 88-an elongated slot; 89-limit bolt.

Detailed Description

The following description of the embodiments of the present application will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present application, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

As shown in fig. 1 and 7, the present application provides an electronic countermeasure home position detection apparatus based on a neural network, which is provided with a detection apparatus host 1, a module mounting frame 2, and a movable housing assembly 3.

The detection equipment host 1 is provided with a detection processing module 4 and a power module 5.

The module mounting frame 2 is arranged in the detection equipment host 1, the module mounting frame 2 is movably provided with a plug track frame 6, the module mounting frame 2 is internally provided with a first cable 7, the detection processing module 4 is arranged on the plug track frame 6, the power module 5 is arranged on one side of the module mounting frame 2 far away from the plug track frame 6, the power module 5 is connected with the module mounting frame 2 through the first cable 7, the module mounting frame 2 and the plug track frame 6 are respectively provided with a connecting interface 9, and a second cable 10 is arranged between the connecting interfaces 9.

The movable storage component 3 is arranged between the connecting interfaces 9, the second cable 10 passes through the movable storage component 3, the second cable 10 extending out of the movable storage component 3 is in a tight state, the movable storage component 3 is movably mounted on the module mounting frame 2, and the movable storage component 3 drives part of the second cable 10 to move out of the movable storage component 3 and drives part of the second cable 10 to be pulled into the movable storage component 3 according to the movement displacement of the plugging track frame 6.

Every interval is provided with a push-down structure 8 on the plug track frame 6, the end part of the push-down structure 8 is abutted with the adjacent plug track frame 6, and the push-down structure 8 pushes the plug track frame 6 to slide so as to adjust the interval between the adjacent plug track frames 6.

In the embodiment of the application, a module mounting frame 2 is arranged in a detection equipment host 1, a pluggable track frame 6 is movably arranged on the module mounting frame 2, a main controller, an intermediate frequency signal processing module, an up-down conversion module, a millimeter wave radio frequency module, a radiation detector and a video analysis module are arranged on the pluggable track frames 6, wherein a pushing structure 8 is arranged on each pluggable track frame 6, the pushing structure 8 pushes the pluggable track frames 6 to slide so as to adjust the interval between adjacent pluggable track frames 6, adjust the heat dissipation gap between adjacent detection processing modules 4, improve the heat dissipation performance, and in addition, the movable storage assembly 3 drives part of the second cables 10 to move out according to the movement displacement of the pluggable track frames 6, so that the displacement of the pluggable track frames 6 can not be pulled by the second cables 10 to realize the adjustment of the heat dissipation gap.

In the application, as shown in fig. 9, the detection processing module 4 comprises a main controller, an intermediate frequency signal processing module, an up-down conversion module, a millimeter wave radio frequency module, a radiation detector and a video analysis module.

Besides the above, in the practical application process, the electronic countermeasure in-situ detection device further comprises auxiliary devices, a remote control terminal, a display and control module and the like, wherein the auxiliary devices comprise an antenna, a tripod and a total station, the antenna and the tripod are connected with each other through a mechanical structure, and the tripod is connected with the total station.

In the above embodiment, the main controller realizes the control of the detection processing module 4, the intermediate frequency signal processing module is used for simulating radar target echo intermediate frequency signals and complex radar signal intermediate frequency signals, the up-down conversion module is used for down-conversion processing of received radar signals, up-conversion processing of simulated radar target echo signals and up-conversion processing of simulated complex radar signals, the millimeter wave radio frequency module is used for up-conversion processing of 18 ghz-40 hz radar signals, the radiation detector is used for analyzing radio frequency signals, and the video analysis module is used for analyzing video signals.

In order to enable the plugging track frame 6 to move according to a certain route, a first sliding groove 11 is formed in the module mounting frame 2, a sliding strip 12 is mounted on the plugging track frame 6, and the sliding strip 12 is slidably arranged in the first sliding groove 11.

When the insertion and extraction track frame 6 is pushed, the sliding bar 12 slides in the first sliding groove 11.

According to the application, the movable storage component 3 drives part of the second cable 10 to move out of the movable storage component 3 and part of the second cable 10 to be pulled into the movable storage component 3 according to the movement displacement of the plugging track frame 6, and the movable storage component 3 adopts the following preferred embodiments, as shown in fig. 2, 3 and 4, the movable storage component 3 comprises a movable barrel 31, a movable shaft column 32 arranged in the movable barrel 31, a thread groove 33 arranged on the movable shaft column 32 and a thread line 34 arranged in the movable barrel 31; the movable barrel 31 and the movable shaft column 32 are coaxially arranged, the movable barrel 31 is movably arranged in the first sliding groove 11, the thread line 34 is matched with the thread groove 33, the side edge of the thread line 34 is abutted against the inner side wall of the thread groove 33, a thread storage groove 35 is formed between the thread line 34 and the thread groove 33, and the second cables 10 are distributed and arranged in the thread storage groove 35.

The second cable 10 is accommodated in the thread accommodating groove 35 and is abutted by the thread line 34, so that the second cable 10 is distributed on the periphery side of the movable shaft post 32 according to the trend of the threads, the second cable 10 cannot move outwards due to the pulling of the two sides, and the second cable 10 is always in a straightening state.

In the above embodiment, the adjacent strands of the second cables 10 are separated by the thread lines 34, so that a certain gap exists between the adjacent strands, and the heat dissipation effect of the second cables 10 is better.

According to the application, the length of the second cable 10 in the horizontal direction is controlled by adjusting the position of the movable shaft column 32 in the movable barrel 31, the movable shaft column 32 is completely arranged in the movable barrel 31 in the initial state, when the movable shaft column 32 is in the outward movement by threads, a thread groove is formed between the second cable 10 and the thread line 34, the corresponding thread groove 33 on the movable shaft column 32 is gradually and spirally moved outward between the thread grooves to drive the right end of the second cable 10 to move inward, the left end of the second cable 10 is moved outward, the moving distance of the movable shaft column 32 is assumed to be x, the moving distance of the second cable 10 is also assumed to be x, but the second cable 10 which is partially moved outward to the outside is not limited by the thread line 34 any more, and the second cable 10 which is positioned at the left end and is positioned outside can gradually separate from the thread groove 33 on the movable shaft column 32 under the action of a tensile force and tends to be in the straight state, at this time, the length of the second cable 10 positioned at the left side is changed, so that the length of the second cable 10 positioned at the left side is changed to be longer, and the length of the second cable 10 can be adjusted according to the horizontal length of the second cable 4 between the detection processing modules 4.

In order to drive the movable shaft column 32 to move outwards in a spiral manner, as shown in fig. 2 and 6, the application also provides a design that a connecting cylinder 36 is further arranged on the side edge of the movable cylinder 31, the connecting cylinder 36 is connected with the side wall of the movable cylinder 31 through a connecting plate 37, the connecting cylinder 36 and the movable cylinder 31 are coaxially arranged, a bottom plate 38 is arranged in the connecting cylinder 36, a through hole 39 for a second cable 10 to pass through is arranged on the bottom plate 38, a threaded bottom column 310 is arranged on the bottom plate 38, a gear cylinder 311 is connected on the threaded bottom column 310 in a threaded manner, the gear cylinder 311 is sleeved outside the threaded bottom column 310, and the end part of the gear cylinder 311 is connected with the movable shaft column 32.

As shown in fig. 2 and 5, a driving cabin 312 is disposed outside the movable cylinder 31 and the connecting cylinder 36, a first driving motor 313 is disposed in the driving cabin 312, an output end of the first driving motor 313 is connected with a gear column 314, a through slot 315 is formed in a side wall of the connecting cylinder 36, a side edge of the gear column 314 passes through the through slot 315, and a side edge of the gear column 314 is meshed with the gear cylinder 311.

In the above embodiment, the first driving motor 313 drives the gear column 314 to rotate, and the gear cylinder 311 is driven to rotate under the rotation of the gear column 314, and the gear cylinder 311 is connected to the threaded bottom column 310 by the threads, so that the gear cylinder 311 gradually moves outwards in a spiral state, and the movable shaft column 32 is also driven to move outwards in a spiral state.

In order to balance the tension of the second cable 10, the application also provides a design that, as shown in fig. 5, a sliding block 316 is arranged on a movable barrel 31, the sliding block 316 is arranged in a first chute 11 in a sliding manner, a rack 317 is arranged on the side edge of the sliding block 316, a connecting cavity 318 is arranged in a module mounting frame 2, and the connecting cavity 318 is communicated with the first chute 11; a connecting gear 319 is arranged in the connecting cavity 318, a second driving motor 320 is connected to the connecting gear 319, the connecting gear 319 is connected to the output end of the second driving motor 320, and the rack 317 is meshed with the connecting gear 319.

The second driving motor 320 drives the connecting gear 319 to rotate, and drives the rack bar 317 to move along the direction of the first chute 11 under the rotation action of the connecting gear 319, so as to drive the sliding block 316 to slide in the first chute 11, and drive the movable tube 31 to face the pulled second cable 10 side, that is, when the right second cable 10 is gradually pulled, the left second cable 10 becomes longer and more relaxed, and the movable tube 31 moves rightward, so that the left second cable 10 is gradually pulled to a straightened state, and the overstretched state of the right second cable 10 is relieved.

In the application, in order to enable the detection processing module 4 to be inserted on the inserting and pulling track frame 6 according to a certain track, the application is designed in such a way that the inserting and pulling track frame 6 is composed of a sliding track wall 61 and a mounting side wall 62, wherein the mounting side wall 62 is vertically arranged on the side edge of the sliding track wall 61, and the sliding track wall 61 is arranged on the module mounting frame 2 in a sliding way; the inside limit of installation lateral wall 62 is provided with slide rail 63, and main control unit, intermediate frequency signal processing module, up-down conversion module, millimeter wave radio frequency module, radiation detector, video analysis module bottom and top are all installed movable strip 64, and movable strip 64 slides and sets up in slide rail 63, and on sliding track wall 61 and be provided with plug interface 13 at connection interface 9 side, main control unit, intermediate frequency signal processing module, up-down conversion module, millimeter wave radio frequency module, radiation detector, video analysis module are last all to install bayonet joint 14, and bayonet joint 14 corresponds to peg graft on plug interface 13.

The movable strip 64 is inserted along the opening of the slide rail 63, and then the corresponding detection processing module 4 is pushed in, so that the movable strip 64 moves in the slide rail 63 until the plug-in connector 14 is plugged into the plug-in connector 13.

In the application, the end of a pushing structure 8 is abutted against an adjacent inserting and pulling track frame 6, the pushing structure 8 pushes the inserting and pulling track frame 6 to slide so as to adjust the interval between the adjacent inserting and pulling track frames 6, the pushing structure 8 adopts the following preferred embodiment, as shown in fig. 8, the pushing structure 8 comprises a driving cylinder 81 penetrating through a sliding track wall 61, a threaded cylinder 82 arranged in the driving cylinder 81, threaded rods 83 arranged in two ends of the threaded cylinder 82 and abutting columns 84 arranged at the end parts of the threaded rods 83, an annular rack 85 is arranged on the outer wall of the threaded cylinder 82, a driving gear 86 is arranged in the driving cylinder 81, the driving gear 86 is meshed with the annular rack 85, a third driving motor 87 is arranged on the driving gear 86, and the driving gear 86 is connected with the output end of the third driving motor 87.

The third driving motor 87 drives the driving gear 86 to rotate, so as to drive the annular rack 85 to rotate, the annular rack 85 drives the threaded cylinder 82 to rotate, and the corresponding threaded rod 83 and the abutting column 84 need to be driven to translate, so that the adjustment of the end position of the abutting column 84 and the position adjustment of the adjacent pluggable track frame 6 are realized.

For this purpose, the application is designed in such a way that a long groove 88 is provided on the abutment post 84, a limit bolt 89 is fixedly provided at the opening of the driving cylinder 81, the end of the limit bolt 89 is provided in the long groove 88, and the limit bolt 89 is engaged with the long groove 88.

Under the limiting action of the limiting bolt 89, the threaded cylinder 82 rotates to drive the threaded rod 83 to gradually move outwards and the abutting column 84 to gradually move outwards, so that the adjacent positions of the plugging track frames 6 are driven to move outwards.

In summary, the main implementation process of the application is as follows:

the movable strip 64 is inserted along the opening part of the sliding rail 63, and then the corresponding detection processing module 4 is pushed in, so that the movable strip 64 moves in the sliding rail 63 until the plug-in connector 14 is plugged into the plug-in connector 13, and the detection processing module 4 is installed;

the third driving motor 87 drives the driving gear 86 to rotate, so that the annular rack 85 is driven to rotate, the annular rack 85 drives the threaded cylinder 82 to rotate, under the limiting action of the limiting bolt 89, the threaded cylinder 82 rotates, the threaded rod 83 is driven to gradually move outwards, the abutting column 84 is driven to gradually move outwards, and the adjacent positions of the pluggable track frames 6 are driven to move outwards, and the gaps between the adjacent detection processing modules 4 are gradually increased;

meanwhile, the first driving motor 313 drives to drive the gear column 314 to rotate, under the rotation action of the gear column 314, the gear cylinder 311 is driven to rotate, the gear cylinder 311 gradually moves outwards in a spiral state, the movable shaft column 32 is driven to move outwards in a spiral state, the right end of the second cable 10 is driven to move inwards, the left end of the second cable 10 moves outwards, and the second cable 10 which moves outwards to the outer movable shaft column 32 is not limited by the thread line 34 any more;

when the second cable 10 on the right side is gradually pulled, the second cable 10 on the left side is gradually and loosely stretched, the second driving motor 320 drives the connecting gear 319 to rotate, and the rack bar 317 is driven to move along the direction of the first sliding groove 11 under the rotation action of the connecting gear 319, so as to drive the sliding block 316 to slide in the first sliding groove 11, drive the movable barrel 31 to move rightward, and the tension force of the second cable 10 on the left end and outside gradually breaks away from the threaded slot 33 on the movable shaft post 32 and tends to be in a straightened state;

the length of the second cable 10 located at the left side is increased, and therefore, the horizontal length occupied by the second cable 10 located between the detection processing modules 4 is increased, and the adaptation is performed in the case that the distance between the detection processing modules 4 is increased, so that the detection processing modules 4 can be freely adjusted without being caught by the second cable 10.

The above embodiments are only exemplary embodiments of the present application and are not intended to limit the present application, the scope of which is defined by the claims. Various modifications and equivalent arrangements of this application will occur to those skilled in the art, and are intended to be within the spirit and scope of the application.

Claims (6)

1. An electronic countermeasure in-situ test apparatus based on a neural network, comprising:

a detection equipment host (1) is provided with a detection processing module (4) and a power supply module (5) inside;

the module installation frame (2) is arranged in the detection equipment host (1), a plug track frame (6) is movably installed on the module installation frame (2), a first cable (7) is installed in the module installation frame (2), the detection processing module (4) is installed on the plug track frame (6), the power module (5) is installed on the module installation frame (2) and far away from one side of the plug track frame (6), the power module (5) is connected with the inside of the module installation frame (2) through the first cable (7), connecting interfaces (9) are arranged on the module installation frame (2) and the plug track frame (6), and a second cable (10) is arranged between the connecting interfaces (9);

the movable storage assembly (3) is arranged between the connecting interfaces (9), the second cable (10) passes through the movable storage assembly (3), the second cable (10) extending out of the movable storage assembly (3) is in a tight state, the movable storage assembly (3) is movably mounted on the module mounting frame (2), the movable storage assembly (3) drives part of the second cable (10) to move out of the movable storage assembly (3) according to the movement displacement of the plugging track frame (6) and drives part of the second cable (10) to be pulled into the movable storage assembly (3);

each interval is provided with a pushing structure (8) on one of the plugging track frames (6), the end part of the pushing structure (8) is abutted with the adjacent plugging track frames (6), and the pushing structure (8) pushes the plugging track frames (6) to slide so as to adjust the interval between the adjacent plugging track frames (6);

a first sliding groove (11) is formed in the module mounting frame (2), a sliding strip (12) is arranged on the plug track frame (6), and the sliding strip (12) is arranged in the first sliding groove (11) in a sliding manner;

the movable storage assembly (3) comprises a movable barrel (31), a movable shaft column (32) arranged in the movable barrel (31), a thread groove (33) arranged on the movable shaft column (32) and a thread line (34) arranged in the movable barrel (31);

the movable cylinder (31) and the movable shaft column (32) are coaxially arranged, the movable cylinder (31) is movably arranged in the first sliding groove (11), the thread line (34) is matched with the thread groove (33), the side edge of the thread line (34) is abutted to the inner side wall of the thread groove (33), a thread storage groove (35) is formed between the thread line (34) and the thread groove (33), and the second cables (10) are distributed and arranged in the thread storage groove (35);

the side of the movable barrel (31) is also provided with a connecting barrel (36), the connecting barrel (36) is connected with the side wall of the movable barrel (31) through a connecting plate (37), the connecting barrel (36) and the movable barrel (31) are coaxially arranged, a bottom plate (38) is arranged in the connecting barrel (36), and a perforation (39) for the second cable (10) to pass through is arranged on the bottom plate (38);

a threaded bottom column (310) is arranged on the bottom plate (38), a gear cylinder (311) is connected to the threaded bottom column (310) in a threaded manner, the gear cylinder (311) is sleeved outside the threaded bottom column (310), and the end part of the gear cylinder (311) is connected with the movable shaft column (32);

a driving cabin (312) is arranged outside the movable cylinder (31) and the connecting cylinder (36), a first driving motor (313) is arranged in the driving cabin (312), the output end of the first driving motor (313) is connected with a gear column (314), a through groove (315) is formed in the side wall of the connecting cylinder (36), the side edge of the gear column (314) penetrates through the through groove (315), and the side edge of the gear column (314) is meshed with the gear cylinder (311);

a sliding block (316) is arranged on the movable barrel (31), the sliding block (316) is arranged in the first sliding groove (11) in a sliding mode, a rack (317) is arranged on the side edge of the sliding block (316), a connecting cavity (318) is arranged in the module mounting frame (2), and the connecting cavity (318) is communicated with the first sliding groove (11);

the connecting cavity (318) is internally provided with a connecting gear (319), a second driving motor (320) is connected to the connecting gear (319), the connecting gear (319) is connected to the output end of the second driving motor (320), and the rack (317) is meshed with the connecting gear (319).

2. The electronic countermeasure in-situ detection equipment based on the neural network according to claim 1, wherein the detection processing module (4) comprises a main controller, an intermediate frequency signal processing module, an up-down conversion module, a millimeter wave radio frequency module, a radiation detector and a video analysis module.

3. The electronic countermeasure home detection apparatus based on a neural network according to claim 2, characterized in that the plug track frame (6) is composed of a slide track wall (61) and a mounting side wall (62), the mounting side wall (62) is vertically mounted on a side of the slide track wall (61), the slide track wall (61) is slidably provided on the module mounting frame (2);

the utility model discloses a video analysis module, including installation lateral wall (62), frequency conversion module, millimeter wave radio frequency module, radiation detector, video analysis module bottom and top, installation lateral wall (62) medial edge is provided with slide rail (63), main control unit intermediate frequency signal processing module up-down conversion module millimeter wave radio frequency module the activity strip (64) are all installed to radiation detector, activity strip (64) slip setting is in slide rail (63).

4. A neural network based electronic counter-home detection device according to claim 3, characterized in that the push-down structure (8) comprises a driving cylinder (81) penetrating the sliding track wall (61), a threaded cylinder (82) arranged inside the driving cylinder (81), threaded rods (83) arranged inside both ends of the threaded cylinder (82) and abutment posts (84) arranged at the ends of the threaded rods (83);

the novel screw thread cylinder is characterized in that an annular rack (85) is arranged on the outer wall of the screw thread cylinder (82), a driving gear (86) is arranged in the driving cylinder (81), the driving gear (86) is meshed with the annular rack (85), a third driving motor (87) is arranged on the driving gear (86), and the driving gear (86) is connected to the output end of the third driving motor (87).

5. The electronic countermeasure home position detection apparatus based on the neural network according to claim 4, characterized in that an elongated slot (88) is provided on the abutment post (84), a limit plug (89) is fixedly provided at an opening of the driving cylinder (81), an end of the limit plug (89) is provided in the elongated slot (88), and the limit plug (89) is engaged with the elongated slot (88).

6. The electronic countermeasure in-situ detection equipment based on the neural network according to claim 5, characterized in that a plug interface (13) is arranged on the sliding track wall (61) and on the side of the connection interface (9), and plug connectors (14) are respectively arranged on the main controller, the intermediate frequency signal processing module, the up-down conversion module, the millimeter wave radio frequency module, the radiation detector and the video analysis module, and the plug connectors (14) are correspondingly plugged on the plug interface (13).