RU219634U1 - AUTONOMOUS SIMULATOR OF UNMASKING SIGNS OF GROUND MILITARY OBJECTS - Google Patents

Abstract

The utility model relates to the field of camouflage, in particular, to technical simulation tools that provide the sudden creation on the ground, in the area of hidden ground military facilities, of a decoy that imitates real unmasking signs (DP) of ground military facilities, and can be used to effectively protect them from modern optoelectronic and radar guidance systems for high-precision weapons (HTO) simultaneously in the visible, infrared (IR) and radar (RL) ranges of electromagnetic wave (EMW) wavelength spectra.

The task of the claimed utility model, which is to increase the efficiency of hiding from reconnaissance equipment, optoelectronic and radar guidance systems of the WTO in the last section of its flight trajectory, by redirecting from a hidden ground military facility to a suddenly created decoy that imitates specific DP, signs of activity and location of an unmasked real ground military facility simultaneously in the visible, IR and RL ranges of the EMW length spectra.

The technical essence of the utility model is achieved by the fact that the autonomous simulator of the DP of a ground military facility installed on the ground surface consists of three blocks that are in functional and constructive unity, which are configured to control the receiving-transmitting and executive functions of the autonomous simulator, which ensure the determination of the time point of sequential reduction from of the transport position of the banner to the working position, on the outer surface of which a color 3D image of a horizontal projection of a simulated uncamouflaged ground military facility on a scale of 1: 1 is applied with visual DP, signs of activity and location, to ensure retargeting of the optical-electronic and radar guidance system of the WTO on the latter section of its flight path with a homing head from the upper hemisphere from a hidden ground military facility to a suddenly created decoy.

Description

The utility model relates to the field of camouflage, in particular, to technical simulation tools that provide the sudden creation on the ground, in the area of hidden ground military facilities, of a decoy that imitates real unmasking signs (DP) of ground military facilities, and can be used to effectively protect them from modern optoelectronic and radar guidance systems for high-precision weapons (HTO) simultaneously in the visible, infrared (IR) and radar (RL) ranges of electromagnetic wave (EMW) wavelength spectra.

One of the ways to counteract the optoelectronic and radar systems of targeting the WTO on ground military facilities is to disrupt the guidance of the optoelectronic and radar means of the WTO in the last section of the trajectory of its guidance to the target being hit, due to the device in the area of the disguised military facility of a decoy that imitates the view DP, signs of activity and location of an undisguised ground military facility [1]. This method provides either a shift in the aiming point of the ammunition during its movement in the last section of the trajectory, or redirection of the ammunition to a false target that suddenly appeared in the field of view of the WTO guidance system. At the same time, a false target should reproduce the DP of an uncamouflaged ground military facility simultaneously in the visible, IR and RL ranges of the EMW length spectra, and its appearance in the field of view of the WTO guidance system must be ensured after establishing the fact of pointing the ammunition at a real target in up to 10 seconds on average ( based on the tactical and technical characteristics of modern WTO).

At present, to counteract modern means of detecting and recognizing real targets of destruction by the applied WTO, false objects are widely used, equipped both in false areas of the deployment of troops, and directly in the area of \u200b\u200blocation of real weapons, military and special equipment (AMSE), which includes engineering equipment simulations of military and military equipment, which, when used, provide an imitation of the DP in the visible (inflatable and other models of military and military equipment, or in the IR (catalytic wick furnace KFP-1-180, Teplo-1 simulator), or in the radar (corner reflectors "OMU", "Ugol ”, “Sphere”, “Pyramid”) ranges of the EMW length spectrum [2].

As a disadvantage of the use of these well-known means of engineering weapons (SIV), taken as analogues, one can attribute, first of all, the fact that they provide DP simulation mainly in only one of the ranges of the EMW length spectrum (or only in the visible, or in the IR in the EMW spectrum, or only in the radar range of the EMW spectrum.At the same time, when using known technical solutions for false single ground military facilities, permanently located on the ground, the timely sudden manifestation of the DP of ground military facilities is not ensured, which, most often, does not allow achieving the required at the same time, their transfer to the working position and installation on the ground are carried out using technical auxiliary installation tools of the installation or manually, which requires significant time and effort. according to the time of installation on the ground of the above known mock-ups that imitate ground military facilities, additional visual DPs arise, signs of the organization of the forces and means involved for deploying mock-ups on the ground from the transport position to the working position, according to which the probability of detecting a false ground military facility by reconnaissance means and accepting its false object almost already after 40-60 min tends to P _rev.l.ob (t)≥0.7.

In order to make a decision based on the results of reconnaissance and accept a false object as a real ground military object with a specified detection probability, it is necessary that the time of its detection does not exceed 20-25 minutes, provided that all the DP inherent in the real hidden ground military object in the visible, IR and RL ranges of EMW length spectra.

A universal simulator of radio electronic means signals [3] is known, which relates to the field of radio engineering, more specifically to means of electronic simulation designed to reproduce signals of electronic means characteristic of various states (conditions of use) of real electronic means for various purposes, as well as generating arbitrary waveforms. The universal simulator of signals of radio electronic means consists of a control electronic computer, a storage device of reference signals of radio electronic means, a complex signal generator, a frequency converter, a power amplifier, an antenna matching device, an antenna-feeder device, a monitoring and control unit, a communication unit and an autonomous power supply . The selected modular design makes it possible to provide the minimum possible weight and size characteristics of the universal simulator of signals of radio electronic means for the required energy potential of the simulated radio electronic means and to reproduce a wide range of signals of real radio electronic means.

The disadvantages of this analogue is that it does not suddenly change the target environment, and from the DP in the visible, IR and RL ranges of the EMW length spectrum, only signals of the own radiation of electronic equipment are reproduced in a constant mode.

An autonomous imitator of unmasking signs of ground objects is known for a sudden change in the target situation in order to counter the WTO [4], which relates to the field of masking, in particular to the means of countering WTO guidance systems for weapons and military special equipment in areas (at positions) of deployment of single and group objects in the thermal and radar ranges of the electromagnetic wave spectrum, consists of an autonomous control system that is in functional and constructive unity, which ensures the determination of the start time of the simulation (successive opening of the reflector and heating) when the ammunition with a thermal and radar homing head is in the last section of the trajectory, and a corner reflector with an automatic opening-closing mechanism.

The main disadvantage of the well-known autonomous simulator is that its use for a sudden change in the target environment in order to counteract the WTO does not provide reproduction of specific DP, signs of activity and location on the ground in the visible range of the EMW spectrum, which, most often, does not allow achieving the required probability disruption of the guidance of optical-electronic and radar guidance systems of the WTO to a military ground object simultaneously in the visible, IR and RL ranges of the EMW length spectra for its effective protection against modern weapons.

A known set of ammunition-cassettes for controlled sudden sharply contrasting crucifixion or aerosol formation in the area of \u200b\u200bthe masked object [5], which relates to the field of masking, in particular, to the means of protecting troops and objects from WTO damage by setting aerosol interference masks, and more specifically volumetrically distributed aerosol formations and/or a sudden sharply contrasting spotting of the terrain background around single objects and in areas (on sites) of group objects.

The technical result of the well-known utility model is achieved by the fact that the cassette ammunition is combined into a set of cassette ammunition for a controlled sudden sharply contrasting spotting or aerosol formation in the area of the masked object with an autonomous control system for detonating ammunition and determining the time of their operation during the flight of a guided WTO submunition in the last section trajectories.

The essence of the utility model is to create a set of ammunition cartridges for controlled sudden sharply contrasting crucifixion or aerosol formation, including a set of ammunition cartridges and a controlled detonation system interconnected with them, including a subsystem of sensors that register changes in the electromagnetic environment and register laser irradiation of the masking object, devices a control device, a decision-making device, a command generation device, and a control radio link for autonomous provision of a sudden sharply contrasting spot or aerosol formation in the area of the masked object at the time of registration of the threshold value of the level of the electromagnetic field and / or laser irradiation by the ammunition guidance systems at the target in the last section of its trajectory , perceived in real time by sensors for detecting signals from guided munitions.

The main disadvantage of the well-known utility model is that its use for a sudden change in the target environment in order to counteract the WTO does not provide a reproduction of specific DP, signs of activity and location on the ground of a real uncamouflaged ground military facility to effectively protect a camouflaged ground military facility from weapons with optical -electronic and radar homing heads of a guided munition to a target from the upper hemisphere, since it does not allow achieving the required probability of failure of munition guidance from a really camouflaged ground military facility to a false target suddenly created in its location zone with signs of a real uncamouflaged ground military facility simultaneously in the visible , IR and RL ranges of EMW length spectra.

The closest in its technical essence and design to the claimed utility model is a radar decoy simulator [6], selected as a prototype.

According to the description, "Radar decoy simulator" related to the means of masking objects and can be used as a "false target", designed to protect an object from radar detection and recognition systems, containing a mesh base, each cell of the horizontal and vertical rows of which is woven flexible tapes made of a material that completely reflects electromagnetic waves, painted on one side in the color of the underlying surface for vegetative or desert-steppe backgrounds, and on the other side - in white, the spectral characteristics of which are close to the color of snow, as well as mounting devices that provide formation of a volume simulating the terrain, having the shape of at least one corner reflector open to the outer surface, the dimensions of which are selected in accordance with the parameters of the terrain.

A significant drawback of the well-known "radar decoy simulator", adopted as a prototype, is, first of all, despite its rapid deployment on the ground to the working position in time (up to 15-20 minutes):

firstly, it has a narrow focus in practice, since it can be used as a "false target" intended only to protect an object from radar detection and recognition systems;

secondly, the well-known utility model is not intended for the sudden creation of a decoy on the ground in the zone of location of hidden ground military facilities that imitates real DPs of ground military facilities and cannot be used to effectively protect them from modern optoelectronic and radar guidance systems of the WTO simultaneously in visible, IR and RL ranges of EMW length spectra.

Thus, the considered known devices, in their functional and constructive unity, do not allow achieving the required result of hiding ground military objects from modern optoelectronic and radar guidance systems of the WTO, since they do not provide a sudden creation on the ground, in the zone of location of hidden ground military objects, of a false target simulating real DP of ground military facilities simultaneously in the visible, IR and RL ranges of EMW length spectra.

The objective of the claimed utility model is to increase the efficiency of hiding from reconnaissance equipment, optoelectronic and radar guidance systems of the WTO in the last section of its flight path, by retargeting from a hidden ground military facility to a suddenly created decoy target that imitates the view of the DP, signs of activity and location an unmasked real ground military facility simultaneously in the visible, IR and RL ranges of the EMW length spectra.

The technical result is achieved by the fact that the autonomous simulator of the DP of a ground military facility installed on the ground surface consists of three blocks that are in functional and constructive unity, which are configured to control the receiving-transmitting and executive functions of the autonomous simulator, which ensure the determination of the time point of sequential reduction from the transport position banner into the working position, on the outer surface of which a color 3D image of a horizontal projection of a simulated uncamouflaged ground military facility on a scale of 1: 1 is applied with visual DP, signs of activity and location, to ensure retargeting of the optical-electronic and radar guidance system of the WTO in the last section of its flight paths with a homing head from the upper hemisphere from a concealed ground military facility to a suddenly created decoy.

The task is achieved by the fact that an autonomous simulator of a DP of a ground military facility installed on the ground surface, containing a mesh electrically conductive base with a flexible polymer coating fixed on it, made of a material reflecting electromagnetic waves, painted in the color of the underlying surface for vegetative or desert-steppe backgrounds, and as well as mounting devices that ensure the fixation of the flexible polymer coating of the decoy simulator on the ground surface;

firstly, it includes three blocks that are in a functional and constructive unity, which are configured to control the receiving-transmitting and executive functions of an autonomous simulator.

At the same time: the first block is made in the form of a banner with a mesh electrically conductive base with a geometric mesh size of (2.0 * 2.0) mm with continuous film coatings pressed from both flat surfaces, painted in the color of the underlying background, with one of the which are a color 3D image of a horizontal projection of a simulated uncamouflaged ground military facility on a scale of 1: 1, on both sides of which, to keep it from sagging in a horizontal working position, along its entire length, two cables are fixed with screwed overhead clamps, and to ensure it is returned - translational movement, from one end edge the banner guide is attached with fixing screws, which is fixed to the cables with overhead clamps and fixing screws.

The second and third blocks are made in the form of a single functional and constructive solution of an autonomous simulator, interconnected separate elements, which include two slabs of bakelite moisture-resistant multilayer plywood with mounting holes for mounting anchors along the perimeter of the slabs and removable protective covers with coaxially installed on both plates of flat support posts (two for each) with bearings pressed into them, in which, respectively, the drive and driven shafts are installed. Moreover, two pulleys for winding the receiving ends of the cables and a pulley for the wedge-belt transmission of rotation of the drive shaft are planted on the drive shaft of the second block at its ends, and one pulley is planted on the driven shaft of the third block from one end to transmit rotation to the driven shaft by means of a wedge- belt transmission in reverse mode for transferring the banner from the transport position to the working position and back, with the ability to control the modes by means of functionally linked to the first electric motor, with the second electric motor and an autonomous power source.

At the same time, the first electric motor with a pulley, together with the remote control system for controlling the receiving-transmitting and actuating devices of the autonomous simulator and the autonomous power source, are bolted on a plate of bakelite moisture-resistant plywood of the second block of the autonomous simulator to ensure the rotation of the drive shaft by means of a wedge-belt drive, and the second electric motor with a pulley is bolted on a plate of bakelite moisture-resistant plywood of the third block to ensure the rotation of the driven shaft by means of a V-belt transmission of the rotation of the driven shaft.

The second and third units are equipped with end limit switches of signal actuators to limit the movement of the banner when it is transferred from the transport position to the working position and back, taking into account the formation by the control system console of the control command to the receiving-transmitting and actuating devices of the autonomous transfer simulator and the time the banner is held in the required position, for which functionally interconnected separate elements with receiving-transmitting and executive functions of an autonomous simulator are combined by power and signal wire lines for controlling an autonomous simulator.

Secondly, to control the receiving-transmitting and executive functions of the autonomous simulator, the remote control system for controlling the receiving-transmitting and actuating devices of the autonomous simulator is additionally equipped with detection sensors that register changes in the electromagnetic environment and fix the registration of laser irradiation of a camouflaged ground military facility, a decision-making and generation device commands and a control radio link, including a command-transmitting device and an actuator to ensure retargeting of the optoelectronic and radar guidance system of the WTO in the last section of its flight path with a homing head from the upper hemisphere from a hidden ground military facility to a suddenly created decoy in the form of an automatically deployed from the transport position to the working position of the banner.

Thirdly, in order to obtain a stable manifestation by an autonomous simulator of unmasking signs of ground military facilities on a suddenly created false target in the last section of the flight path of a WTO ammunition with an optoelectronic and radar homing head from the upper hemisphere, in the composition of camouflage dyes or pigments used for protective coloring continuous film coating and applying to its outer surface a color 3D image of a horizontal projection of a simulated uncamouflaged ground military facility on a scale of 1:1, a 5% aqueous composition of a hydrosol of silver cations with a silver concentration of 12 mg/l of aqueous dispersion was introduced.

The essence of the technical solution of the claimed utility model is shown in Fig. 1, 2, 3, 4, 5.

In FIG. 1 shows a schematic diagram of a technical solution for an autonomous DP simulator of a ground military facility, which includes three blocks that are in functional and constructive unity, where:

1 - offline simulator banner; 2 - mesh electrically conductive base of the banner; 3 - continuous film coating, painted to match the color of the underlying background; 4 - color 3D image of a horizontal projection of a simulated uncamouflaged ground military facility on a scale of 1:1; 5 - cable; 6 - banner guide; 7 - plate made of bakelite moisture-resistant plywood; 8 - mounting holes; 9 - removable protective covers; 10 - flat support post; 11 - bearing; 12 - drive shaft; 13 - driven shaft; 14 - pulley for winding the receiving ends of the cable; 15 - pulley of the wedge-belt transmission of rotation of the drive shaft; 16 - pulley for transmitting rotation to the driven shaft by means of a wedge-belt drive; 17 - the first electric motor; 18 - the second electric motor; 19 - autonomous power supply; 20 - pulley of the first electric motor; 21 - console of the control system for receiving-transmitting and actuating devices of an autonomous simulator; 22 - bolted connection; 23 - wedge-belt drive; 24 - pulley of the second electric motor; 25 - wedge-belt transmission of rotation of the driven shaft; 26 - terminal limit switches.

In FIG. 2 shows a schematic diagram of the structural elements of an autonomous simulator of a DP of a ground military facility located on the second block of structural elements, which is in functional and structural unity with the first and second blocks of an autonomous simulator, where: 7 - a slab of bakelite moisture-resistant multilayer plywood; 9 - removable protective cover; 10 - flat support post; 11 - bearing; 12 - drive shaft; 14 - pulley for winding the receiving ends of the cable; 15 - pulley of the wedge-belt transmission of rotation of the drive shaft; 17 - the first electric motor; 19 - autonomous power supply; 20 - pulley of the first electric motor; 21 - console of the control system for receiving-transmitting and actuating devices of an autonomous simulator; 22 - bolted connection; 26 - terminal limit switches; 27 - power and signal wire lines for controlling an autonomous simulator; 28 - mounting anchor.

In FIG. 3 shows a schematic diagram of the fastening of the cable 5 to the electrically conductive mesh base of the banner 2 and the banner guide 6, where: 2 - electrically conductive mesh base of the banner; 5 - cable; 6 - banner guide; 29 - invoice clamp; 30 - fixing screw.

In FIG. Figure 4 shows a schematic block diagram of the control panel for the control system for receiving-transmitting and actuating devices of an autonomous simulator of a DP of a ground military facility, where:

1 - offline simulator banner; 21 - console of the control system for receiving-transmitting and actuating devices of an autonomous simulator; 31 - detection sensors; 32 - device for making decisions and generating commands; 33 - radio control line; 34 - command-transmitting device; 35 - executive device.

In FIG. Figure 5 shows a variant of the schematic diagram of an autonomous simulator of unmasking signs of a ground military facility installed on the soil surface in a half-profile of a trench with the manifestation of specific DP, signs of activity and location.

Implementation of a utility model for the purpose of retargeting from a hidden real ground military facility to a suddenly created false target that imitates its specific DP, signs of activity and location simultaneously in the visible, IR and RL ranges of the EMW length spectra, to provide imitation of a ground military facility using the claimed utility model “Autonomous simulator of ground military objects DP” manufactured and assembled in the factory, by the crew (crew) of a camouflaged real ground military object, is installed on the ground in the area of location of a camouflaged real ground military object at a given distance of the munition deflection radius (R _off.b ) from the target being hit .

A variant of the schematic diagram of an autonomous DP simulator of a ground military facility installed on the ground surface in a semi-profile of a trench with the manifestation of specific DP, signs of activity and location is shown in Fig. 5.

Also, the claimed utility model can also be used in the location of an autonomous simulator of a DP of a ground military facility openly located on the ground in the area where a disguised real ground military facility is located using technical means of concealment (this option is not shown in Fig.).

To provide imitation of a real non-camouflaged ground military facility from reconnaissance equipment and WTO guidance systems simultaneously in the visible, IR and RL ranges of EMW length spectra, in the claimed "Autonomous simulator of ground military facilities DP", containing: a mesh base with a flexible polymer coating attached to it , made of a material reflecting electromagnetic waves, painted in the color of the underlying surface for vegetative or desert-steppe backgrounds, as well as mounting devices that ensure the fixation of the flexible polymer coating of the decoy simulator on the soil surface, includes three blocks that are in functional and structural unity (see Fig. 1), which are configured to control the transceiver and executive functions of the autonomous simulator.

At the same time, the first block is made in the form of a banner (1) with a mesh electrically conductive base (2) with a geometric mesh size of (2.0 * 2.0) mm with continuous film coatings pressed from both flat surfaces, painted in the color of the underlying background (3 ), with printed on the outer surface of one of which is a color 3D image of the horizontal projection of the simulated

uncamouflaged ground military facility on a scale of 1:1 (4), on both sides of which, to keep it from sagging in a horizontal working position, along its entire length, two cables (5) are fixed with screwed overhead clamps (29), and to ensure it reciprocating motion, from one end edge the banner guide (6) is attached with fixing screws (30), which is fixed to the cables (5) with overhead clamps (29) and fixing screws (30).

The second and third blocks are made in the form of a single functional and constructive solution of an autonomous simulator, interconnected separate elements, which include two slabs of bakelite moisture-resistant plywood (7) with mounting holes (8) for mounting anchors (30) along the perimeter of the slabs (7) and removable protective covers (9) with flat support posts (10) coaxially mounted on both plates (two for each) with bearings (11) pressed into them, in which, respectively, the driving (12) and driven (13) ) shafts. Moreover, on the drive shaft (12) of the second block, two pulleys (14) are planted at its ends for winding the receiving ends of the cable (5) and a pulley for the V-belt transmission of rotation of the drive shaft (15), and on the driven shaft (13) of the third block one pulley (16) is mounted at one end to transmit rotation to the driven shaft (13) by means of a wedge-belt drive (25) in reverse mode to transfer the banner (1) from the transport position to the working position and vice versa, with the possibility of controlling the modes by means of a functionally linked with the first electric motor (17), with the second electric motor (18) and autonomous power supply (19).

At the same time: the first electric motor (17) with a pulley (20), together with the remote control system for the control system of receiving-transmitting and actuating devices of an autonomous simulator (21) and an autonomous power source (19), are bolted (22) on a slab of bakelite moisture-resistant plywood (7) the second autonomous imitator block to ensure the rotation of the drive shaft (12) by means of a wedge-belt transmission (23), and the second electric motor (18) with a pulley (24) is bolted (22) on a plate of bakelite moisture-resistant plywood (7) a third block for ensuring the rotation of the driven shaft (13) by means of a V-belt transmission for the rotation of the driven shaft (25);

the second and third blocks are equipped with limit switches (26) of signal actuators to limit the movement of the banner (1) when it is transferred from the transport position to the working position and vice versa, taking into account the formation by the control system console (21) of the control command to the receiving-transmitting and actuating devices of the autonomous simulator translation and holding time of the banner (1) in the required position, for which functionally interconnected individual elements with the receiving-transmitting and executive functions of the autonomous simulator are combined with power and signal wire lines for controlling the autonomous simulator (27).

Secondly, to provide the ability to control the receiving-transmitting and executive functions of an autonomous simulator of unmasking signs of a ground military facility, the remote control system for controlling the receiving-transmitting and actuating devices of an autonomous simulator (21) is additionally equipped with detection sensors (31) that register a change in the electromagnetic environment and fix the registration of a laser irradiation of a camouflaged ground military facility, a decision-making and command generation device (32) and a control radio link (33), including a command-transmitting device (34) and an actuator (35) to ensure retargeting of the optoelectronic and radar guidance system of the WTO in the last section its flight path with a homing head from the upper hemisphere from a hidden ground military facility to a suddenly created false target in the form of a banner (1) automatically opened from the transport position to the working position.

Thirdly, in order to obtain a stable manifestation by an autonomous simulator of unmasking signs of ground military facilities on a suddenly created false target in the last section of the flight path of a WTO ammunition with an optoelectronic and radar homing head from the upper hemisphere, in the composition of camouflage dyes or pigments used for protective coloring continuous film coating (3) and applying to its outer surface a color 3D image of a horizontal projection of a simulated unmasked ground military facility on a scale of 1:1 (4), a 5% aqueous composition of a hydrosol of silver cations with a silver concentration of 12 mg/l of aqueous dispersion is introduced.

As is known, the following technical solutions are implemented in the WTO guidance systems, which allow determining the mutual position of the ammunition and the target:

illumination of the target with specific radiation, allowing the ammunition to identify the target and correct its deviation;

the use of target radiation in the entire spectrum of the wavelength range;

the ability of the ammunition to identify the optical or radio technical picture of the target in order to select a priority object when pointing the submunition.

The technical essence of the remote control system for controlling the receiving-transmitting and actuating devices of the autonomous simulator (21) with the ability to control the receiving-transmitting and executive functions of the autonomous simulator is introduced into the "Autonomous simulator of unmasking signs of ground military facilities" installed on the surface of the soil, is that to determine the moment guidance of a guided WTO submunition at a target in the last section of its trajectory in the claimed utility model, detection sensors (31) are included in the remote control system for the control system for receiving-transmitting and actuating devices of an autonomous simulator (21), registering a change in the electromagnetic environment or a change in the mode of operation of the radar of the guidance system, and also registering laser irradiation of the camouflage object.

Detection sensors (31) record the exposure of a ground military facility with an optoelectronic and radar system for pointing a guided submunition at a target at the last stage of its trajectory or the operation of a laser guidance system, transmit data to a decision-making and command generation device (32). The device for making a decision and generating commands (32) algorithmically determines the threshold values, upon reaching which a decision is made for the control command to the receiving-transmitting and actuating devices of the autonomous simulator of transferring from the transport position of the banner of the autonomous simulator (1) to the working position and the time it is held in the required position , and transmits the command to the command-transmitting device (34) of the control radio link (33).

The command-transmitting device (34) generates a command and transmits it to the actuator (35) of the control radio link (33).

The effectiveness of the claimed utility model was evaluated based on the results of simulation modeling of the manifestation of unmasking signs of a ground military facility by an autonomous simulator in the visible, IR and RL ranges of the EMW length spectrum [7].

The well-known simulation model for evaluating the effectiveness of the use of FCM of typical single and group homogeneous ground objects from optoelectronic and radar reconnaissance equipment is based on the developed methodological approach to substantiate the criterion assessment of the effectiveness of concealment and imitation of single and group ground military objects, and takes into account the variety of masking methods, different scale their use in the course of performing tasks, as well as the specifics of camouflage measures for ground military facilities.

The application of this program made it possible to calculate and compare the effectiveness of the application of the studied variants of the FCM of a ground military facility in the coverage area of reconnaissance technical means in the simulated conditions of the tasks performed.

The program made it possible to calculate the selected criteria for evaluating the effectiveness of the studied FCM of a single ground military facility, taking into account the sequential input of the generated initial data, including variable values of parameters and indicators characterizing the tactical and technical capabilities of the technical means of reconnaissance and guidance systems of the WTO, the performance characteristics of the ground military facility with the studied options for its camouflage, the surrounding air environment and the underlying background of the area.

The program provided:

reproduction of the process of detecting a single military object by technical means of ground, air and space reconnaissance of the armies of foreign states, conducting air reconnaissance at low, medium and high altitudes and space reconnaissance, taking into account the possibility of using simulated options for using technical means of hiding a ground military object and simulating it using the claimed useful model, physical parameters of the underlying surface of the terrain background and the atmosphere;

calculation of the selected criteria for assessing the effectiveness of camouflage of a single ground military facility in case of a one-time contact of the technical means of reconnaissance and guidance of the WTO guidance systems with a ground military facility, taking into account typical situations of the tasks performed;

output of the results of calculation of criteria, its indicators and parameters for evaluating the effectiveness of simulated camouflage options for a single military object in numerical and graphical forms for their further analysis (Computer type: IBM PC-compatible computer. Language: Action scripts 2OC: Windows 7).

On the basis of the simulation modeling, it was found that the required values of the physical parameters of the spectral characteristics of the FCM of a ground military facility are functionally determined primarily by the required values of the probability of its detection P _det (t) during a single contact of reconnaissance equipment with a ground military facility in the visible, IR and RL spectral ranges lengths of EMW conducting reconnaissance at low (up to 1000 m), medium (up to 5000 m), high (up to 10000 m) altitudes and space reconnaissance.

In order for a ground military facility to complete the task in a timely manner, it is known that its survivability must be Q(t)≥0.7, which is determined in the first approximation by the well-known formula:

where: R _obn.i (t) - the probability of detecting a ground military object by means of intelligence;

P _n - the probability of pointing optoelectronic and radar guidance systems of the WTO at a ground military facility as part of a group ground military facility;

Р _por - the probability of hitting a ground military facility

Where: - the probability of hitting a target as part of a group facility (without creating a false single military facility in the area where a real ground military facility is located);

- the same, with the creation of a false single military facility in the area where a real ground military facility is located;

Р _obni - the probability of detecting the i-th single object in the group object

where: C is a coefficient that takes into account the impact on the quality of interpretation of the position and number of single objects (a real ground military facility in the presence of a false ground military facility);

B - shape recognition coefficient of a single ground military object, m;

- natural size of a single ground military facility;

- resolution of the image of a ground military facility;

m is the image scale of a ground military facility;

K - the contrast of the image of a ground military object relative to the underlying background of the terrain.

With a given probability of destruction Р _por =0.8, in order to ensure the required survivability of a single or group ground military object Q(t), it is necessary that the probability of its detection be Р _det (t)≤0.37.

It is known [8] that for the visible, IR and RL ranges of the EMW length spectrum, the simulated adaptive variable is the brightness, temperature and radar contrasts of the ground military facility relative to the underlying terrain background, respectively.

To determine the probability of detection of a camouflaged ground military facility with the use of technical means of concealment in the visible range of the EMW length spectrum, in practice, the luminance contrast (K _view ) of the object's surfaces relative to the background, taken by the modulo, is more often used, which is provided by reducing the spectral luminance factor of the applied FCM of ground military facilities, calculated by the formula [1,8]

where: r _about , r _f - spectral coefficients of brightness of the object and background.

To determine the probability of detection camouflaged ground military facility using technical means of concealment in the IR range of the EMW length spectrum, in practice, the temperature contrast (K _IR ) of the surfaces of the object and the background, taken by the modulo, is more often used, provided by lowering the coating temperature to the required level, which can be calculated by the formula [1 ,8]:

where: T _about , T _f - radiation temperature of the object and background, respectively, in degrees Celsius or Kelvin.

The radiation temperature is related to the thermodynamic temperature by the following relationship:

where: ε _p is the emissivity (or grayness factor) of the material (surface).

Then formula (6) will take the form:

where: T _about and T _f - thermodynamic temperatures of the object and background, respectively, in degrees Kelvin.

In the RL range of the EMW length spectrum, the unmasking feature is the RL "portrait" of the object. Quantitatively, RCS is calculated as the ratio of the energy of an equivalent isotropic source to the energy flux density (J/m ² ) of probing radio emission at the location of the scatterer.

where: R is the distance from the radar to the ground military facility, ρ ₁ is the power flux density of the incident wave of a given polarization at the target location, ρ ₂ is the power flux density of the wave of the given polarization reflected from the target at the radar location.

To determine the probability of detection of a camouflaged ground military facility with the use of technical means of concealment in the radar range of the EMW length spectrum, in practice, the radar contrast (K _rl ) of a ground military facility relative to the underlying terrain background is more often used.

The radar contrast between an unmasked object and the underlying terrain background can be expressed by the well-known expression [8]:

where: σ _about - EPR of a ground military facility;

- EPR of the underlying terrain background;

δS is the area of the resolvable surface by means of reconnaissance;

S ₀ - area occupied by a ground military facility;

σ _pore - threshold EPR, determined by the characteristics of the technical means of exploration.

It follows from expression (9) that the radar contrast of a ground military facility relative to the underlying terrain background is determined by the reflective properties of the object and background, radar parameters and reconnaissance conditions and is an important intermediate indicator.

The effectiveness of the application of simulated variants of technical means of concealing ground military facilities is determined by the possibility of its detection during the period of operation.

The criterion for non-detection of a camouflaged military facility using technical means of concealment simultaneously in the visible, IR and RL ranges of the EMW length spectrum is the probability of detecting a camouflaged ground military facility (P _obt ) provided:

where: Р _det - the required value of the probability of detection

a camouflaged ground military facility in the visible, IR and RL ranges of the EMW length spectrum using technical means of concealment.

In turn, the probability of hitting (Р _thr ) a target as part of a group object is defined as the probability of a normally distributed random variable x falling into a given interval (a, b), with known values of M and σ [9]:

Where:

- mathematical expectation of a discrete random value of the aiming point from the true target of the defeat;

L _i - the value of the random value of the deviation of the specified value by the decoder operator.

σ is the root mean square deviation of the point of aim of the means of destruction from the true target as part of a group object.

According to the results of the mathematical modeling of the criterion assessment of the effectiveness of hiding and simulating single and group ground military facilities using the claimed utility model, it was found that, with the accepted quantitative values of indicators and parameters of the simulated options for hiding a real ground military facility using the studied options for technical means of hiding a single military facility and the creation of a false ground military facility in the area of its location, it was found that when an uncamouflaged false ground military facility is used in the area of location at a given distance from the concealed ground military facility, the probability of its detection during a single contact of a reconnaissance means with an autonomous simulator is the probability of detecting a false object and accepting it for the actual R _obn.l./d =0.8 with the probability of aiming the means of destruction at the target P _n =0.9 and its probability of hitting P _then =0.85. Under these conditions, taking into account the above dependence (1), the survivability (Q) of a false ground military facility, in the form of an autonomous simulator of unmasking signs of a ground military facility equipped at a given distance from a hidden ground military facility, is Q = 0.39, which confirms the feasibility of practical implementation the claimed utility model.

At the same time, the probability of detecting a camouflaged ground military during a single contact of a reconnaissance tool with an autonomous simulator is P _oi =0.35 with the probability of pointing the weapon at the target P _n =0.4 and its probability of hitting, taking into account the location of the decoy P _{n. d/l.} =0.25.

Under these conditions, taking into account the above dependence (1), the survivability of a real ground military facility camouflaged using an effective simulated version of multispectral technical means of concealment in the visible, IR and RL ranges of the EMW length spectrum of a ground military facility while simultaneously located in the area of the concealed ground military facility of a false ground military facility in the form of an autonomous simulator of unmasking signs of a ground military facility is Q = 0.96, which can ensure the fulfillment of the task by the ground military facility.

The obtained camouflage effect to provide imitation of a false object using the claimed utility model in the context of the use of modern reconnaissance equipment with optoelectronic radar systems for targeting a target is achieved through the complex manifestation of unmasking features of the claimed autonomous simulator of an uncamouflaged real ground military object simultaneously in the visible, IR and radar ranges of the EMW length spectrum during its practical operation.

Firstly, for the manifestation of the simulated visual DP of a real uncamouflaged ground military facility in the visible range of the EMW length spectrum, a color 3D image of a horizontal projection of a simulated uncamouflaged ground military facility on a scale 1:1 (4) with the use of protective camouflage coloring to match the color and structure of the natural grass cover of the surrounding background of the area [10] while providing light stabilization of the spectral luminance coefficients (SCR) of camouflage dyes or pigments with a spectral luminance coefficient r _vol = 0.45 of the dyes used for protective coloring uncamouflaged ground military equipment against the underlying background of a green meadow with its spectral brightness coefficient _rf =0.18, due to the introduction of 5% aqueous composition of the hydrosol of silver cations into their composition with a silver concentration of 12 mg/l of aqueous dispersion [11];

Secondly, the manifestation of the imitating visual DP of a real unmasked ground military facility in the IR range of the EMW length spectrum of an autonomous simulator installed on the ground surface is carried out by an autonomous simulator banner automatically opening from the transport position to the working position (1) due to additional condensation of water vapor from the surrounding air on continuous film coatings (3) pressed into the mesh electrically conductive base (2) from both flat surfaces, painted in the color of the underlying background using camouflage dyes or pigments with an additional 5% aqueous composition of silver cation hydrosol with a silver concentration of 12 mg / l of aqueous dispersion with the formation of continuous film coatings on both sides of flat surfaces (3), a highly polarized electric field with an electric field strength (U _B = 2.5 * 10 ⁷ V / m) [11], causing clustering of water vapor from both surface flat continuous film coatings (3), with the formation of a time-stable greenhouse effect on their surfaces with a temperature difference between the underlying vegetation background of the area and the inner surface of the continuous film coating (3), with simultaneous radiation heating of the soil under the continuous film coating, painted in color underlying terrain background (3) autonomous simulator banner (1) with a temperature difference relative to the underlying terrain background of at least ±3.0-5.0°C relative to the surrounding terrain background, and thereby ensuring the manifestation of specific DP, signs of activity and location on the terrain of an autonomous simulator in the IR range of the EMW spectrum.

Thirdly, the manifestation of simulating visual DPs of a real unmasked ground military facility in the radar range of the EMW length spectrum installed on the ground surface of an autonomous simulator is carried out by an autonomous simulator banner automatically opening from the transport position to the working position (1) due to the re-reflection of the radiation of the ground-based radar detection tool. military facility in the direction of the line of sight "reconnaissance and guidance systems of the WTO - a decoy simulator", made in the form of a banner with an autonomous simulator (1) with a mesh electrically conductive base (2) with a geometric mesh size of (2.0 * 2.0) mm , reflecting 50% of electromagnetic radiation in power with a specific surface resistance W = 75.0 Ohm relative to the standard of a metal plate, to ensure retargeting of the radar guidance system of the WTO in the last section of its flight path of a guided submunition with a homing head from the upper hemisphere from a concealed ground military facility to suddenly created false target.

At the same time, the presence of continuous film coatings (3) on both flat surfaces, painted in the color of the underlying background using camouflage dyes or pigments, additionally introduced into their composition is a 5% aqueous composition of the hydrosol of silver cations with a silver concentration of 12 mg/l in an aqueous dispersion with the formation on both sides of the flat surfaces of continuous film coatings (3), a highly polarized electric field with a strength (U _B \u003d 2.5 * 10 ⁷ V / m), causing clustering of water vapor from both surface flat continuous film coatings (3), with the formation of a time-stable greenhouse effect on their surfaces, provides real-time re-reflection of the radiation of a radar detection tool of a ground military facility towards the line of sight "reconnaissance and guidance systems of the WTO - a decoy target simulator" reflecting 50% of electromagnetic radiation in terms of power with specific surface resistance W=75.0 ohms relative to the ethanol of the metal plate.

The surface resistivity of a banner (1) with a mesh electrically conductive base (2) with a geometric mesh size of (2.0 * 2.0) mm was measured according to GOST R 53734.2.3-2021 "Methods for determining the electrical resistance of solid flat materials used for the purpose of prevent the accumulation of electrical charge. With the accepted geometrical dimensions of the mesh (2.0 * 2.0) mm, the mesh electrically conductive base (2) achieves a reflection of 50% of electromagnetic radiation in terms of power with a specific surface resistance W=75.0 Ohm relative to the ethanol of the metal plate.

Thus, the claimed utility model "Autonomous simulator of unmasking signs of ground military facilities" ensures the fulfillment of the formulated task, which consists in increasing the efficiency of concealment from reconnaissance equipment, optoelectronic and radar guidance systems of the WTO in the last section of its flight path, due to retargeting from a concealed ground a military facility to a suddenly created decoy that imitates visual DP, signs of activity and location of an undisguised real ground military facility simultaneously in the visible, IR and RL ranges of the EMW length spectra.

List of sources used

1. Krivelev V.A. and others. Camouflage of troops and military facilities: Textbook. - M: VIA, 1996, p. 253.

2. Manual on military engineering for the armed forces of the Russian Federation. - M.: 2016, p. 104-107.

3. Universal simulator of signals of radio electronic means” / T.P. Radchenko, O.E. Fashchenko, A.A. Slepnev, V.V. Gaidarenko, S.D. Matkovsky. - Patent for a utility model of the Russian Federation No. 184182. - 27.07. 2018. - Published: 10/18/2018. Bull. No. 29.

4. Autonomous simulator of unmasking signs of ground objects for a sudden change in the target situation in order to counter the WTO / D.Yu. Shchetinin, A.A. Baranov, V.P. Gerasimenya. - Patent for a utility model of the Russian Federation No. 193373. - 2019. - Bull. No. 31.

5. A set of ammunition-cassettes for a controlled sudden sharply contrasting crucifixion or aerosol formation in the area of the masked object / V.P. Gerasimenya, A.A. Baranov, N.M. Komarovsky, V.I. Seleznev - Patent for a utility model of the Russian Federation No. 175624. - 2016. Published: 12/12/2017, Bull. No. 35.

6. Radar simulator of a false target / L.G. Ustimenko, D.N. Vladimirov, V.P. Gerasimenya, N.N. Kostyunin, L.M. Suslov, E.N. Khandogina - Patent for a utility model of the Russian Federation No. 81571 dated 05.11.2008 - 2008. - Publ. 03/20/2009.

7. Gerasimenya V.P., Baranov A.A. Simulation model for evaluating the effectiveness of the use of technical means of masking typical single and group homogeneous ground objects from optoelectronic and radar reconnaissance equipment. Certificate of state registration of the computer program No. 2021619042 dated 06/03/2021. According to the application No. 2021618262 dated May 28, 2021

8. Menshakov. Yu.K. Fundamentals of protection against technical intelligence: study guide / Yu.K. Menshakov; under total ed. M.P. Sychev. - M.: Publishing house of MSTU im. N.E. Bauman, 2014.

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10. Disguise. Part 1. The basis and technique of disguise. Textbook by V.A. Efimov, V.E. Kolchevsky, S.G. Chermashentsev. - M.: VIA, 1971. - S. 189-216, Chapter IX. Camouflage coloring.

11. Gerasimenya V.P., Klykov M.A., Zakharov S.V., Slepnev A.A., Kutavin A.N., Vavilova S.S. - Patent RU for the invention 2640925 dated September 19, 2016. Method for obtaining dyed textile materials treated with silver cation hydrosol with a complex of light-stabilizing, antimicrobial and antitoxic properties. Published on January 12, 2018, Bull. No. 2.

Claims (3)

1. An autonomous simulator of unmasking signs of ground military facilities, containing a mesh base with a flexible polymer coating fixed on it, made of a material reflecting electromagnetic waves, painted in the color of the underlying surface for vegetative or desert-steppe backgrounds, as well as mounting devices that provide fixation of the flexible polymer coverage of a decoy simulator on the ground surface, characterized in that the autonomous simulator of unmasking signs of a ground military facility installed on the ground surface includes three blocks that are in functional and constructive unity, which are configured to control the receiving-transmitting and executive functions of an autonomous simulator, with In this case: the first block is made in the form of a banner with a mesh electrically conductive base with a geometric cell size of 2.0 * 2.0 mm with continuous film coatings pressed from both flat surfaces, painted in the color of the underlying background, with one of which is coated on the outer surface with colored 3D - images of a horizontal projection of a simulated unmasked ground military facility on a scale of 1: 1, on both sides of which, to keep it from sagging in a horizontal working position, along its entire length, two cables are fixed with screwed overhead clamps, and to ensure its reciprocating motion from one end edge, a banner guide is attached with fixing screws, which is fixed to the cables with overhead clamps and fixing screws, the second and third blocks are made in the form of a single functional and constructive solution of an autonomous imitator, interconnected individual elements that include two slabs of moisture-resistant bakelite plywood with mounting holes for mounting anchors along the perimeter of the plates and removable protective covers with flat support posts coaxially mounted on both plates, two for each, with bearings pressed into them, in which, respectively, the drive and driven shafts are installed, moreover, on the drive shaft of the second block, two pulleys for winding the receiving ends of the cables and a pulley for the V-belt transmission of rotation of the drive shaft are planted on its ends, and one pulley is planted on the driven shaft of the third block from one end to transmit rotation to the driven shaft by means of a V-belt transmission in reverse mode to transfer the banner from the transport position into operation and back, with the ability to control the modes by functionally linked to the first electric motor, with the second electric motor and an autonomous power source, while: the first electric motor with a pulley, together with the remote control system for transmitting and receiving and actuating devices of an autonomous simulator and an autonomous source power supplies are bolted on a plate of bakelite moisture-resistant plywood of the second block of an autonomous simulator to ensure the rotation of the drive shaft by means of a V-belt drive, and the second electric motor with a pulley is bolted to a plate of bakelite moisture-resistant plywood of the third block to ensure the rotation of the driven shaft by means of a V-belt drive rotation of the driven shaft; the second and third units are equipped with end limit switches of signal actuators to limit the movement of the banner when it is transferred from the transport position to the working position and vice versa, taking into account the generation of a control command by the control system console to the receiving-transmitting and actuating devices of an autonomous transfer simulator and the time the banner is held in the required position, for which functionally interconnected separate elements with receiving-transmitting and executive functions of an autonomous simulator are combined by power and signal wire lines for controlling an autonomous simulator. 2. An autonomous simulator of unmasking signs according to claim 1, characterized in that the remote control system for controlling the transceiver and actuators of the autonomous simulator is additionally equipped with detection sensors that record changes in the electromagnetic environment and record the registration of laser irradiation of a camouflaged ground military facility, a decision-making and generation device commands and a control radio link, including a command-transmitting device and an actuator to ensure retargeting of the optoelectronic and radar guidance system of high-precision weapons in the last section of its flight path with a homing head from the upper hemisphere from a hidden ground military facility to a suddenly created false target in the form of automatically unfolded from the transport position to the working position of the banner. 3. An autonomous simulator of unmasking signs according to claim 1, characterized in that in order to obtain a stable manifestation by an autonomous simulator of unmasking signs of ground military objects on a suddenly created false target in the last section of the flight path of a high-precision weapon ammunition with an optoelectronic and radar homing head from the upper hemisphere in the composition of camouflage dyes or pigments used for protective coloring of a continuous film coating and applying to its outer surface a color 3D image of a horizontal projection of a simulated uncamouflaged ground military facility on a scale of 1: 1, a 5% aqueous composition of a hydrosol of silver cations with a silver concentration of 12 mg was introduced /l of water dispersion.