RU2132036C1 - Video trainer for rifleman - Google Patents

Abstract

FIELD: small arms training aids. SUBSTANCE: invention is intended for expansion of possibilities of modeling various situation with usage of small arms and approximation of training process to real conditions. Mentioned result is achieved thanks to employment of screen manufactured in the form of concave polyhedron in video trainer on which coordinate marks are applied with the use of paint fluorescing in ultraviolet rays, to use of ultraviolet radiator, adjustment mechanisms with video projector directed on one of faces of screen mounted on each of them. Video projectors are fitted with controlling drives of zoom lenses. Video input of each projector is connected to output of proper videorecorder which in its turn is linked to synchronization unit. EFFECT: expanded possibilities of modeling various situations with usage of small arms. 4 dwg

Description

 The invention relates to devices for training or aiming training and to the field of training aids, namely to shooting simulators for training military personnel, security service shooters, training athletes and hunters.

 A device is known for an optical-electronic shooting simulator (copyright certificate of the Russian Federation N 445822, M. Cl. F 41 J 1/18), consisting of a weapon simulator equipped with a directional light source and a radio transmitter, a photoelectric target from a matrix of photosensitive elements and projection means onto a target of various light moving targets. Such a device allows you to simulate shooting on flying saucers, shooting on a flying duck, shooting on a running boar, however, the visibility of such a simulation is not sufficient, and the number of options for simulating a shooting situation is limited.

 Known equipment for simulating shooting in hostilities (US Patent N 4917609, CL 434 - 20), which contains a training weapon with an optical sight, a tracking system for the direction of the weapon with sensors of vertical, horizontal and azimuthal orientation, a system for introducing a television image into an optical sight. This equipment allows you to visually simulate various combat situations, but the shooter sees the situation in the narrow field of view of the optical sight, although in most real cases, the military, security guard or hunter have to evaluate the operational situation in a large sector of the surrounding space.

 The prototype is a room simulator device (US Patent No. 4,657,551, cl. 434-20), which consists of a screen, projection means in front of the screen to demonstrate a moving image containing at least one target on the screen in visible light, at least one weapon, having a trigger for the day of the shot, an infrared radiation source, a video camera in front of the screen for converting the video image on the screen, a retractable infrared radiation filter in front of the video camera, computing means for correcting the position of the infrared emitter trace depending on the shooting conditions. Means of presenting the results of shooting, as well as means of sound simulation.

 The disadvantage of the described device is a significant limitation of the observation sector (up to 60-70 degrees), in which the training tactical situation is simulated, which is associated with the technical impossibility of reproducing on one screen an undistorted image of large angular dimensions. And this significantly limits the possibility of using the described device to train the personnel of security and military organizations to solve the problems of defense of a protected object or person, in which, as a rule, there are situations when an attack on an object (person) is conducted from several directions, which requires observation and use of weapons to defeat in the sector up to 360 degrees. Similar problems arise when training athletes and hunters for whom the sector of the use of weapons ranges from 180 to 270 degrees.

 The aim of the invention is to expand the modeling capabilities of various situations with the use of small arms and approximate the training process to the real conditions of a wide spatial review of the operational environment. These requirements arise, for example, when training security guards, who usually conduct surveillance in a sector with large angular dimensions, or training hunters whose target can appear anywhere in the entire surrounding space, to train athletes in firing on a circular booth. This goal is achieved through the use of a screen made in the form of a concave polyhedron, in combination with several video projectors, each of which is directed to the corresponding face of the screen. This design of the screen in combination with a multi-projector system makes it possible to obtain a vivid image with a training arrow coverage of up to 360 degrees horizontally and 180 degrees vertically. However, the simple application of a multi-projector system does not allow to obtain a high-quality image due to the presence of mismatches of the projections of individual projectors both in space and in time. Therefore, a necessary condition for achieving this goal is the introduction into the device of the coordinate and time coordination system (adjustment) of the projectors. At the same time, the adjustment system should include a set of coordinate marks applied to the face of the multifaceted screen with fluorescent paint, alignment (guiding) mechanisms on which video projectors are installed, equipped with zoom lenses with electric drives, video recorders connected by video outputs with video inputs of video projectors, and control inputs connected to a synchronization unit, as well as sources of ultraviolet radiation, while the control inputs of the adjustment mechanisms, zoom actuators, UV radiation sources are connected respectively to the outputs of the alignment controller, zoom controller and ultraviolet emitter controller, which in turn are connected with the control inputs of the synchronization unit to the bus of the personal computer in parallel with the control inputs of the synchronization unit.

 The introduction of these elements allows you to align the projection system in such a way as to ensure coordinate and temporal coincidence of images on individual faces of the screen.

 Introduction to the device screen, made in the form of a concave polyhedron and multi-projector system, equipped with a coordinate and time adjustment system, allows to obtain a new quality compared to the prototype, namely to increase the spatial viewing angle of the trainee and provide enhanced modeling capabilities for various shooting situations.

 Based on this, we can conclude that, in comparison with the prototype, the proposed technical solution meets the criterion of "significant differences" and the criterion of "novelty."

 In FIG. 1 shows a general view of a shooting video simulator in plan; FIG. 2 shows a general side view of a shooting video simulator, in FIG. 3 is a structural diagram of the electronic equipment of a shooting video simulator; FIG. 4 shows the device of the adjustment mechanism.

 In FIG. 1 and FIG. 2 shows a general view of a video simulator, which consists of a screen 1 operating in clearance and made in the form of a concave polyhedron of translucent material containing ten flat screens and placed in space using a system of stretch marks, a training weapon 2 with an infrared radiation source 3 installed on it, ten video projectors 4, attached to the adjustment mechanisms 5, which in turn are mounted on the brackets 6. Zoom mechanisms 7, which are located on the adjustment mechanisms, are also installed meshes with the zoom lever on video projectors. The brackets 6 are also equipped with ten cameras 8, which are equipped with movable infrared filters 9 mounted on the axis of the drives 10. Four ultraviolet emitters 11 are installed behind the screen, and coordinate marks in the form of two points are applied using fluorescent paint on each side of the screens, one of which located in the geometric center of the face, and the second - on the line of intersection of the face with a vertical plane passing through the center of the face and the top edge of the face.

 The electronic equipment and signal communications included in the video simulator are shown in FIG. 3. The input signal of the VHS standard is fed to the video projectors 4 from their respective video recorders 12, the control inputs of the video recorders 12 are connected to the outputs of the synchronization unit 13, made in the RS232 standard. TTL signals from the outputs of the adjustment controller 14 are supplied to the control inputs of the adjustment mechanisms 5, and the control inputs of the power zoom drives 7 are connected to the TTL outputs of the zoom controller 15. The output VHS signals from the video cameras 8 are fed to the inputs of ten analog-to-digital conversion units 16, and the inputs of the drives 10 infrared filters are connected to the TTL outputs of the infrared controller 17, ultraviolet emitters 11 are connected to the output of the ultraviolet emitter controller 18. The audio synthesizer unit 19 connected to an audio amplifier with an audio system 20, the printer controller 21 is connected to a color laser printer 22. The synchronization unit 13, the alignment controller 14, the zoom drive controller 15, the analog-to-digital conversion units 16, the infrared mode controller 17, the ultraviolet emitter controller 18, the audio unit synthesizer 19 and printer controller 21 are installed in the crate of a Pentium personal computer 23 and connected to its information control bus.

 In FIG. Figure 4 shows the device of the adjustment mechanism, which consists of a base 24, with a stepping electric rotation motor 25 mounted on it and stepping electric motors 26, 27. A worm gear 28 is mounted above the base on thrust bearings and is in mesh with the worm fixed on the motor axis 25. There are mounting holes on the worm wheel for attaching the adjustment mechanism to the bracket 6. From below, a pivot pin 29 is attached to the base, onto which a table 30 is suspended through the pivot joint. worm wheels 31 are mounted to the base through thrust bearings, having screw threads in the axial channels. The worm wheels 31 are engaged with the worms fixed on the axis of the electric motors 26, 27. Screw traverses 32 are mounted in the screw channels of the worm wheels 31, on which a table 30 with a video projector 4 is mounted on the ends through the tie rods 33 with crosses at the ends 4. On the table 30 a stepping motor for driving the zoom 7 is also installed, which, through a plug 34 fixed on its axis, is engaged with the zoom lever of the video projector.

 The device operates as follows. From the keyboard of the personal computer 23 in the dialogue mode, the necessary training film is selected. At the same time, through the synchronization unit of the VCRs 13, the corresponding code number of the start mark of the given film is transmitted via the RS232 interface and the VCRs 12 are set to the initial position, at the same time, the infrared filter drives are turned on via the infrared controller 17 and the infrared filters are removed from the camera lenses. With a time delay for the actuation time of the infrared filter drives, the ultraviolet emitters 11 are switched on by a command through the controller of the ultraviolet emitter 18, which excite the fluorescence of the coordinate marks on the edges of the screen 1 by their radiation. Digital conversion 16 transmit the video signal to the memory of a personal computer. After reading the video signal of the coordinate labels, a command to turn off the ultraviolet emitters is generated, and a command to set the first frame of the adjustment table is sent to the video recorders 12. In this frame, a point corresponding to the projection center of the video projectors 4 is projected onto each face of the screen 1. The video images of the projection centers of the video projectors 4 are read by video cameras 8 and compared with the video images of the geometric centers of the faces of the screen that were read when the ultraviolet radiation sources were turned on. The result of this comparison is the horizontal and vertical distances between the centers of the faces of the screen and the centers of the projections of the corresponding video projectors. The digital values of these distances with the opposite sign through the adjustment controller 14 are supplied to the stepping motors of the adjustment mechanisms 5. In this case, the horizontal displacement code is supplied to the stepping motor of rotation 25, and the vertical displacement code is supplied in parallel to the stepping motors of inclination 26 and 27, thereby ensuring alignment projection centers of video projectors with centers of screen faces. (If more precise alignment is necessary, several iterations of this process can be carried out). After combining the centers of the projections of the video projectors with the centers of the corresponding faces of the screen, the VCRs 12 are transferred to the demonstration mode of the second frame of the adjustment table, on which a vertical line is drawn passing through the center of the projection. Camcorders 8 transfer these images to a personal computer, where these images are compared with the image of the coordinate labels of the edges of the screen 1. In this case, the distances from the vertical lines in the projected image to the points located on the vertical line above the marks of the centers of the edges of the screen are calculated. The digital values of these distances through the adjustment controller 14 are fed to the stepper motors of the tilt 27 of the adjustment mechanisms of the corresponding screen faces with a positive sign, and to the stepper motors of the tilt 26 with a negative sign, which causes the projectors to rotate around their optical axes and ensures the alignment of the projected image verticals and the verticals of the faces screen. (If more precise alignment is necessary, several iterations of this process can be carried out). After that, the video recorders 12 are transferred to the demonstration mode of the third frame of the adjustment table, which shows the top frame line of the video projectors 4. The video cameras 8 read the images of the top lines of the frame frames, which are then compared with the coordinate mark images on the corresponding upper edges of the edges of the screen. As a result of this comparison, the distances between the corresponding images of the upper lines of the projection frame frames and the coordinate mark images on the upper edges of the edges of the screen are calculated. The digital values of these distances with the opposite sign through the controller of the drives of the zoom 15 are fed to the respective drives of the zoom of the video projectors 7, as a result of which the scale of the projected images changes and the frame sizes of the video projectors coincide with the sizes of the corresponding edges of the screen, which ensures that the images are shown in geometric patterns on all faces of the multifaceted screen 1. This process can also be repeated several times for a more accurate ovmescheniya.

 After adjusting the projection system to the VCRs 12, a clock frequency starts to be supplied through the synchronization unit 13, which synchronizes the simultaneous frame-by-frame display of the training film on a multifaceted screen. Through the use of such a mode of operation of video recorders and the use of the timing of their work, temporary synchronization of the video display on all faces of the screen 1 is ensured.

 Simultaneously with the start of the training film, the infrared controller 17 sends a command to introduce infrared filters 9 into the field of view of the cameras 8, and the training shooter takes a shooting position in the center of the multifaceted screen.

 During the demonstration of the training film, the training shooter monitors the operational situation of the actions developing on the screen and, upon detection of the target, opens fire. During the trigger of the training weapon 2, the source of infrared radiation 3 emits a focused beam on the screen. At the same time, a splash appears in the video signal of one of the cameras, which determines the place where the shot hit the screen. When a burst appears in the video signal, the block of the audio synthesizer 19 through the audio amplifier with the audio system 20 reproduces the sound effect of the shot. The coordinates of the location of the shot are stored in the computer's memory. Based on these coordinates and the source data tables for the demonstrated training film, the flight time of the bullet (fraction) in the simulated situation is determined by the range of the target. After this time, the number of the current frame of the training film is remembered, the film is not interrupted, and the shooter, if it is necessary to hit another target, fires the next shot, the coordinates of which are also recorded in the computer 23 memory along with the frame number of the video corresponding to the estimated time delay. Subsequent shots are recorded similarly.

 After the training film is finished, a command is sent through the infrared controller 17 to the infrared filter drives 10, which divert the infrared filters from the field of view of the cameras 8, and upon command through the synchronization unit, the video recorders begin to display the training film frame corresponding to the first shot. The image of this frame is read by video cameras 8 and through the analog-to-digital conversion unit 16, the personal computer 23 and the printer controller 21 are output to a color laser printer 22, and the defeat field of the used ammunition (bullet, buckshot, shot) is superimposed on the image. If necessary, the same image is displayed on a computer monitor, evaluated by the instructor, the trainee himself and recorded on the hard drive. Information on all shots fired by the shooter during the training film is similarly displayed.

 The described device allows you to reproduce a high-quality, undistorted image of the surrounding space in a wide viewing angle, which creates an emotional and psychological impact on the trainee, as close as possible to a real (combat) situation. Thus, the use of a multi-screen system equipped with a coordinate and temporal adjustment (linking) system of fragments of a multi-screen image with each other provides the possibility of modeling a wide class of situations (scenes) using small arms with the training process being as close as possible to the actual situation in which you have to act, given factors of the entire environment.

Claims (1)

 A shooting video simulator containing a screen, video projectors connected to video recorders with a training film, a weapon with an infrared radiation source installed on it, video receiving equipment equipped with movable infrared filters, as well as control and presentation equipment in the form of a personal computer, characterized in that the screen is made in the form of a concave polyhedron with coordinate marks that are fluorescent in ultraviolet light and deposited on its face, while the video simulator It is loaded with a controlled ultraviolet emitter and an ultraviolet emitter controller connected to it, adjustment mechanisms, each of which has a video projector directed to one of the sides of the screen, electric zoom actuators, which are engaged with the levers of the zoom projectors, a synchronization unit, the control outputs of which are connected to control inputs of video recorders, each of which is connected to the video input of the corresponding video projector by its video output , an alignment controller, the outputs of which are connected to the adjustment mechanisms, and a zoom drive controller, the outputs of which are connected to the inputs of the electric zoom drives, while the inputs of the synchronization unit, the adjustment controller, the zoom drive controller, the ultraviolet emitter controller are connected in parallel to the information and control bus of the personal computer .

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