EA026222B1 - Advertising animation device - Google Patents

Abstract

The present invention relates to advertising. An advertising animation device comprises light boxes (3) installed in a tunnel (1) along the path of motion of a train (2), said light boxes (3) having disposed therein a system for scanning a horizontally-compressed image of individual pictures that represent a phase of motion of an overall storyline using a narrow, vertically-installed light source (4) and a mirror reflector (5), wherein the scanning of an image of an individual plate having a film frame (6) is situated between the light source (4) and the viewer. The system is provided with a cylindrical lens (7) having a slit shutter (8) installed along the axis of the lens, the central line of the slit coinciding with the axis (9) of the lens, behind which, installed at a focal distance, is a plate having a film frame (6) which is equal in length to the lens, the center of the radius of curvature of said plate coinciding with the axis (9) of the lens (7), wherein the light source (4) is installed parallel to the lens (7) and the plate (6), and the mirror reflector (5) is in the shape of an arc of an ellipse and is installed at a distance at which light stream from the light source (4) is focused on the central axis (9) of the lens (7), passing through the plate having an image of a film frame (6). The technical result is increasing the coefficient of light transmission of the system, which increases the brightness of an image while reducing electricity consumption.

Description

(57) The invention relates to the field of advertising. The advertising and animation device contains light boxes (3) mounted in the tunnel (1) along the train track (2) with a scanning system for horizontally compressed images of individual paintings, which are the phase of the general plot using a vertically installed narrow light source ( 4) and a mirror reflector (5), while scanning the image of a single plate with a film frame (6) is located between the light source (4) and the viewer. The system is equipped with a cylindrical lens (7) with a slit shutter (8) installed along the axis of the lens, the center line of the slit of which coincides with the axis (9) of the lens, behind which a plate with a film frame (6) is installed at the focal distance, which is equal to the length of the lens part of the cylindrical surface, the center of the radius of curvature of which coincides with the axis (9) of the lens (7), while the light source (4) is installed in parallel with the lens (7) and the plate (6), and the mirror reflector (5) has the shape of an ellipse arc and installed at a distance at which the light otok from the light source (4) is focused on the central axis (9) of the lens (7), passing through the plate from the image film frame (6). Effect: increases the system transmittance, which enhances the brightness of the image while reducing power consumption.

026222 B1

Technical field

The present invention relates to advertising and design technologies and is intended to create a cinematic (animation) effect outside the window of a vehicle moving in a darkened space, for example, in a subway tunnel or railway or on a highway (railway section) in the dark.

State of the art

Of the earliest patents related to advertising in subways, railways, and motor vehicles, US Patent No. 2,299,731, 1942, which describes a system of flash lamps mounted on moving vehicles, is known. Displays carrying a series of photographs in series with the phases of motion of the cinematic scene are illuminated with high-frequency flash lamps.

After 30 years, a stroboscopic system for reproducing animation phases was described in US patent No. 3694062 and 3951529.

Of all the systems, the most widely used system was developed by Joshua D. Spodek in collaboration with the authors, described in US patent No. 6564486 of May 20, 2003 and called 8bteb1a. The essence of the invention is that a number of backlit, highly compressed horizontally compressed images of the animation phases are set in the display. Opposite each image, at a certain distance from it, an opaque screen is installed with a narrow vertical slit, which is located between the image and the audience-passengers. When the train moves relative to the displays of this system, an animation effect is created. Variants of the SysheFa system are shown in subsequent patents I8 No. 6718666 B2 dated April 13, 2004, I8 No. 6731370 B1 dated May 4, 2004, and I8 No. 6807760 B2 dated October 26, 2004.

System 8iSheb1a is successfully used in world media markets, including New York, Washington, Chicago, Atlanta, Boston, Hong Kong and Mexico City. Nevertheless, this system suffers from a number of drawbacks, which, first of all, include an extremely low light transmission coefficient - 1-1.5% of the used light power, which inevitably leads to high energy consumption. It is also noteworthy that with a ratio of the slit size of 0.5-0.6 mm to the width of the film frame of 47-50 mm, the horizontal sharpness of the resulting image is greatly affected. The printed material, which carries the image phases, occupies the entire display area, as a result of which a rather large total area of this material is required for the manufacture of the roller, which is also a drawback, since the cost of the roller increases its cost.

Closest to the proposed invention are the development of §1erie R. Nshek, displayed in patents I8 No. 7827712 B2 dated November 9, 2010 and I8 No. 7870686 B2 dated January 18, 2011. We will dwell on the analysis of the last patent selected as a prototype.

The principle of constructing an animated image according to the invention-prototype is based on scanning a horizontally compressed image using a vertically mounted, narrow (1 pixel) light source, when the scanned image of a single film frame is located between the light source and the passenger-viewer, and the optimal viewing distance of the image by the viewer many times greater than the distance of the light source from the material (LCD, film slide) carrying the image.

The inventor sets as his task the construction of an image having a horizontal viewing angle of not more than 33.64 ° and vertical - not more than 25.55 °, as well as a resolution of not more than 242 horizontal pixels. The proposed resolution parameter is clearly inferior to the parameters of existing conventional video standards, not to mention the increasingly popular BUT format. Given the horizontal size of a single film frame formed on a transparent LCD, 103.12 mm, the size of a pixel equal to the width of a narrow light source (gap in front of a fluorescent lamp, LED strip coated with a vertical diffuser, neon tube, open mini-fluorescent lamp, reflection source in a mirror cylindrical surface), is "0.43 mm.

In the case of using the slit installed in front of the fluorescent lamp (Fig. 12, 13), a large loss of light power is inevitable due to the excess of the diameter of the cylindrical bulb of the lamp by several tens of times compared with the size of the slit.

The option using a mini-fluorescent lamp (Fig. 10, 11) is not very realistic due to the fact that such lamps with a bulb diameter of 0.43 mm and a length sufficient to illuminate the entire vertical frame (0.5-0.6 m), simply not produced by world industry.

The option using a neon tube seems unrealistic (Fig. 8, 9). In addition, the manufacture of a tube with the aforementioned cross-sectional diameter is a technically difficult task, the light efficiency of such a tube would be extremely small.

More successful and original look options associated with the reflection of a fluorescent lamp in a mirror cylindrical surface (Fig. 18-32), since they make it possible to obtain a light strip of the desired width when choosing a certain distance from the lamp to a cylindrical mirror and the radius of curvature of the latter. A common problem with these design solutions is that the fluorescent lamp should be at a distance from

- 1,026,222 of a cylindrical surface sufficient to cause reflection in the form of a thin luminous strip. Since the radius of curvature of the reflecting surface is small, the surface area is also small. Thus, the working section of the cylinder facing the fluorescent lamp occupies only a small sector in the circle of uniform distribution of light energy of the lamp, which inevitably leads to irrational consumption of light flux. The fact that a reflecting surface of the same configuration is symmetrically located on the other side of the lamp does not fundamentally solve the problem.

The most successful option proposed in this patent seems to be the embodiment illustrated in FIG. 14-16, in which an LED strip in combination with a vertical diffuser of a lens-raster type is proposed as a scanning light source to give the light source a continuous character. In general, most of the options proposed by the author of the prototype patent are suitable for creating an animated effect outside the windows of a subway train, if you stay within the framework of those modest tasks that they are assigned: horizontal and vertical viewing angles in the above values. When trying to go beyond these parameters in the direction of a significant increase in horizontal resolution, for example, 800-1000 pixels and higher, we will encounter the need to reduce the pixel size several times, respectively, the width of the emitting band, which will inevitably lead to greater light loss, and will not allow creating image of sufficient brightness and cast doubt on the appropriateness of using the principles set forth in this patent.

Disclosure of invention

The objective of the invention is to eliminate the disadvantages of the prototype, as well as obtaining a better image and reducing eye fatigue of the observer.

This problem is solved using the signs specified in claim 1, common with the prototype, such as an advertising animation device containing light boxes mounted in a tunnel along the train’s route with a scanning system of horizontally compressed images of individual paintings representing a phase general plot movements using a vertically mounted narrow light source and a specular reflector, while scanning an image of a single plate from a film frame m is located between the light source and the viewer, and distinctive essential features, such as a system equipped with a cylindrical lens with a slit shutter installed along the axis of the lens, the center line of the slit of which coincides with the axis of the lens, behind which a plate with a film frame is installed at the focal distance, which is equal to along the length of the lens is a part of the cylindrical surface, the center of the radius of curvature of which coincides with the axis of the lens, while the light source is installed in parallel with the lens and the plate, and the mirror reflector It has the shape of an ellipse arc and is installed in the region in which the light flux from the light source is focused on the central axis of the lens passing through the plate from the image film frame.

According to claim 2, the plate with the image is made in the form of a film slide with a geometrically modified - narrowed image width of one frame of a reproduced movie scene or an elastic, transparent liquid crystal display with the size and shape of a film slide onto which a fixed frame of an animated plot is transmitted using a computer programs.

According to claim 3, the lens is made of an optically transparent material, for example glass or plastic, or in the form of a cylindrical tube of a transparent material filled with a liquid, for example water or a mixture of transparent and colorless liquids.

According to claim 4, with an interval of placement of light boxes on the tunnel wall relative to each other less than 0.3 m, several image scanning systems are preferably installed in each light box, and with an interval of 0.7-1.0 m or more, one image scanning system preferably placed in a separate light box.

The above set of essential features allows you to get the following technical result: the system transmittance increases, which increases the brightness of the image while reducing power consumption. Thanks to this, the effect of the video on the viewer-passenger is enhanced. It is also possible to significantly increase the intervals between light boxes, which allows you to install the system in tunnels of high-speed railways without significantly increasing the cost of the displayed spectacle. The ability to feed images with a frequency of 75 Hz and above, as a result of which the smoothness of movement of the dynamic parts of the image when they are perceived by the viewer-passenger is ensured and the fatigue of the organs of vision is reduced. Thanks to the use of a cylindrical lens with a slit shutter inside it, the horizontal and vertical viewing angles can reach significant values, and in combination with high clarity, the viewing conditions approach the conditions of film screening in the системе system, which also enhances the impact on the passenger-viewer. Due to the fact that the image of the phase of the animation plot is a separate narrow strip of film with a horizontally compressed image, the width of which is many times less than the interval between light boxes, the total area of the printed material is saved and the printing process is cheaper. In addition, individual slide strips with animation phases make it possible to change the order of their installation in the light box system and to demonstrate the same plot on both sides of train cars, unless the plot or its fragments are designed for the appearance of the 3E effect . The design of the light box is suitable for replacing the film slide with an LCD, identical to the slide in shape and size, without significant alterations to the design. When installing LCD displays in the scanning system, the process of replacing video material in the device is significantly cheaper. The optical scheme of the device contributes to a significant reduction in the dimensions of the product, compared with existing analogues (the size from the back wall of the device to its front border), which allows it to be installed in closer tunnels and, thus, contributes to the wider application of the invention in the metro tunnel system.

The invention is illustrated by drawings.

In FIG. 1 shows a General view of the placement of the proposed device in the tunnel; in FIG. 2 - image scanning system; in FIG. 3 is a top view of the optical circuit of the device.

The best example of carrying out the invention

The advertising animation device contains (Fig. 1) light boxes 3 mounted in the tunnel 1 along the train route 2 with a scanning system for horizontally compressed images of individual paintings that are a phase of the general plot using a vertically mounted narrow light source 4 (Fig. 1). 2) and a mirror reflector 5, while scanning an image of a single plate with a film frame 6 is located between the light source 4 and the viewer. The system is equipped with a cylindrical lens 7 with a slit shutter 8 mounted along the axis 9 of the lens 7 (Fig. 3), the center line of the slit of which coincides with the axis 9 of the lens 7, behind which a plate with a film frame 6 is installed at the focal distance, which is equal to the length of the lens 7 is a part of a cylindrical surface, the center of the radius of curvature of which coincides with the axis 9 of the lens 7, while the light source 4 is installed in parallel with the lens 7 and the plate 6, and the mirror reflector 5 has the shape of an ellipse arc and is installed at a distance at which the light otok from the light source 4 is focused on the central axis 9 of the lens 7 passes through the plate 6 with a picture film frame.

The plate with image 6 is made in the form of a film slide with a geometrically modified narrowed image of one frame of a reproduced movie scene or an elastic, transparent liquid crystal display with the size and shape of a film slide onto which a fixed frame of an animated plot is transmitted using a computer program.

The lens 7 is made of an optically transparent material, for example glass or plastic, or in the form of a cylindrical tube of a transparent material filled with a liquid, for example water or a mixture of transparent and colorless liquids (Fig. 3).

When the interval of placement on the tunnel wall (Fig. 1) of the light boxes relative to each other is less than 0.3 m, several image scanning systems are preferably installed in each light box, and with an interval of 0.7-1.0 m or more, one image scanning system is preferably placed in a separate light box. The operation of the proposed device is based on the property of human vision to remember the trace of a luminous object moving relative to the observer or arising from the movement of the observer relative to the luminous object.

An advertising device for creating an animation effect is a group of light boxes with image scanning systems mounted along the wall of a tunnel or on the side of a railway (or highway) with equal intervals between them.

Scan system device.

On the front (facing the viewer-passenger) side of the light box is a vertically arranged cylindrical tube 7 made of a transparent material, filled with pure water (or another transparent, colorless liquid, a mixture of transparent liquids).

Inside the tube, in the central longitudinal section of the cylinder, there is a thin strip (slotted shutter) 8 of opaque material with a narrow gap along the strip. The center line of the slit coincides with the axis 9 of cylinder 7. Thus, the tube is a cylindrical objective lens, where the slit serves as a diaphragm.

Behind the cylindrical lens 7, at a focal distance from it, is a film slide 6 with a geometrically modified (greatly narrowed in width) image of one frame of a reproduced movie scene. The film slide is a transparent film glued to a narrow strip 6, which is part of a cylindrical surface, made of solid transparent material (glass, plastic) with a radius of curvature on the short side. The center of the radius of curvature coincides with the axis 9 of cylinder 7. The slide is located along the cylindrical lens in such a way that the central longitudinal image line is parallel to the axis of the cylindrical lens, and each point of the film image is equidistant from it. The image surface of the film slide coincides with the focal surface of the cylindrical lens 7.

The second embodiment of the image of the frame is an elastic, transparent LCD 3 026222 display, identical in size and shape of its working surface with the dimensions and shape of a film slide, placed between 2 strips of solid transparent material having radii of curvature on the short side, calculated so so as to ensure a tight, without gaps, pressure on both sides of the LCD, and so that the radius of curvature of its working side coincides with the axis of the lens, and each point of its working surface coincides with the focal ited lens.

In the further text of the description, the word slide will mean both versions of the image frame.

Behind the film slide, along a cylindrical lens, along its entire length (or slightly exceeding its length at both ends equally), there is a strip (mirror reflector) of solid material (plastic, glass, metal). The short side of the strip has the same bend along a curve representing an arc of an ellipse along the entire length of the strip. The inner side of the strip facing the film slide has a mirror coating. At a certain distance from the lens, parallel to it, along its entire length (or slightly exceeding the length of the lens at both ends equally), there is a light source 4, which is an emitting strip with a minimum radiation width, facing the mirror strip. In the case of the propagation of the light flux through 360 °, the source 4 should be equipped with a screen in order to exclude direct light from it in the eyes of the passenger.

As a light-emitting strip (light source) 4, an LED strip with a special diffuser can be used to make the radiation front continuous and uniform in length, as well as rod-type halogen lamps whose incandescent fibers are optically arranged vertically, along a straight line, without a gap. A rod-type fluorescent, neon or mini-fluorescent lamp with a minimum cross-section of the radiating tube can also be used. The minimum width of the radiation source is required so that in a focused form (with the help of a mirror strip) the light flux from it could pass entirely (or for the most part, with minimal losses) through the slit of the lens shutter. From how minimized the width of the slit depends on the sharpness of the image horizontally. The ratio of the transmittance of the scanning system and, ultimately, the brightness of the image depends on the ratio of the width of the slit to the width of the source. With equal values of the gap width and the width of the light source, the light transmission coefficient will be close to 1 (100%).

The device operates as follows.

The luminous flux emitted by source 4 (Fig. 3) is directed toward the mirror reflector 5 and, reflecting from its surface, shines through slide 6 and focuses on the center line of the slit of the shutter 8 located in the central section of the cylindrical lens 7. The mirror reflector 5 is located on the back side system of a cylindrical lens - slide in such a way that the segment O O ¹ , which is the axis of symmetry of the ellipse arc, is the bisector of the angle AO ¹ A ¹ , where point A coincides with the center of the slit of the lens shutter, and point A ¹ with c center of the light source. The ellipsoid sectional curve of the mirror reflector is designed so that the luminous flux from the light source is focused at the center of the slit. This optical design provides a horizontal viewing angle for the viewer-passenger up to 90 °. Theoretically, this angle can be increased by a small amount.

The viewer-passenger, looking towards the light box, at each point of his location relative to him sees the vertical line of the image corresponding to this point, focused in his eyes by a cylindrical lens. In the process of moving relative to the light box, the totality of these lines is formed in the consciousness of the viewer-passenger in the image of one frame of a cinematic scene. In the figure, the arrow shows the direction of movement of the viewer-passenger relative to the light box. Corresponding to this movement, the order of arrangement on the slide of elementary vertical lines of the image of the film frame occurs in the opposite direction.

A cylindrical lens with a slit shutter mounted in its section can be made in the form of a monolith from any transparent, colorless material, such as glass or plastic.

Create an animated image.

If the light boxes with the cinema frames installed in them are arranged along the roadway, along the roadside, with a certain equal interval, in the immediate vicinity of the vehicle’s windows in accordance with the direction of movement (the best conditions for this are a railway tunnel or a subway tunnel), then a cinematic (animated) effect. In this case, the interval must be selected such that, in accordance with the speed of the vehicle, the flicker frequency of the light trail would exceed the critical one. The interval between the center lines of the slots of the shutter of a cylindrical lens is calculated by the formula:

where a is the interval;

- 4 026222

V is the average speed (m / s); γ is the required flicker frequency.

For example, at a subway train speed of 13.9 m / s (50 km / h), the required flicker frequency of 75 Hz, the interval is “0.185 m.

In tunnels designed to run trains at a speed of 69.4 m / s (250 km / h), the interval at 75 Hz will be “0.925 m.

It is advisable to choose a frequency of 75 Hz for reasons of its multiplicity to the standard video frequency of 25 Hz. When using captured video material with this frequency, each source frame should be printed in 3 copies for 3 adjacent scanning light box systems. But at the same time, manufacturers of video material (commercials) are given the opportunity to shoot the source material (or simulate it using computer animation) with a frequency of 75 Hz. In this case, one of the captured frames will be installed in each scanning system, which will ensure smooth movement of the dynamic image details. If desired, you can change the frequency of stroboscopy (preferably not lower than 60 Hz for reasons of perception comfort) by changing the intervals between them. In this case, it will be necessary to correlate it with the shooting frequency of the captured video material to calculate the order in which this material will be printed for installation in light boxes. The process of this calculation can be automated using a program specially created for this. Or, the manufacturers of the video material, by prior agreement with the installers of light boxes, will remove (or simulate) it with the required frame rate. The pace of the demonstrated animated image largely depends on the speed of the vehicle passing by the advertising installation, and it may be unstable. In this case, it is recommended to calculate the intervals in accordance with the average (most frequently used) speed. It should be noted that the intervals between the light boxes relative to each other can affect the design of advertising devices. So, for example, at intervals of less than 0.3 m, it is advisable to place them in pieces in the common housing of the light box. When using an interval of 0.7-1.0 m (this is possible in the tunnel of a high-speed train of the Sapsan type), it is advisable to place each projector module in a separate building.

The nature of the image.

The horizontal viewing angle of the generated image coincides with the horizontal angle of projection of the light box, is a constant value, regardless of the distance between the viewer and the passenger plane of the location of the slit shutter lens. The vertical angular size of the image varies with this distance. Due to this circumstance, the ratio of the horizontal and vertical angles of the image coincides with the aspect ratio of the film frame at the optimal, pre-calculated distance from the eyes of the spectator passengers to the plane of the slit shutter. When changing the observation distance, a slight geometric distortion of the frame occurs. So, when the viewer-passenger approaches the car window, the vertical angular size of the image increases, because of which it is slightly elongated vertically, and vice versa: when moving away from the window by a distance greater than the optimum, the vertical angular size decreases, and the image is slightly compressed vertically (it seems elongated horizontally).

It should be noted that each vertical elementary strip of the image is sequentially fixed by the right and left eye of the observer at the same angle. Thus, each point in the image is perceived by parallel-tuned eyes (convergence angle = 0 °). This creates the illusion of the infinite remoteness of the perceived object, which causes a feeling of spaciousness and scale, like an image in a movie theater with a very large screen. Under certain certain conditions, a 3I effect may even occur. This is possible if objects shot by moving around them appear in the frame (or the nature of the movement of the virtual camera will be set during computer simulation). The main condition for the occurrence of such an effect is the coincidence of the direction of traffic with the movement of the camera during a detour (preferably slow) around the subject. Another condition is the close, close to the eye base arrangement of light boxes.

Create an image on a slide.

Since the slide is narrow in width, the ratio of its width to height is very different from the actual proportions of the resulting image. A slide is an image that is highly compressed in width with a height that has a natural size. The width compression ratio is calculated as follows:

The value obtained by the ratio of height to width of the slide is multiplied by the value obtained by the ratio of height to width of the captured image. For example, the height of the slide is 1000 mm, the width is 40 mm.

The ratio of 1000: 40 "25.

Aspect ratio 4: 3 = 1.33 ...

The compression ratio is 25x1.33 ... "33.25.

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With a frame ratio of 16: 9 = 1.77 ... the compression ratio is 25x1.77 ... "44.25.

All calculations should be started by determining the optimal distance from the eyes of the passenger’s viewer to the plane of the slit shutter of the cylindrical lens. The calculation takes into account various factors: the location of the seats in the train cars, the width of the tunnel itself and much more. Having determined this distance, knowing the horizontal projection angle embedded in the design of the scanning system, choosing the aspect ratio of the future image, we can determine the vertical viewing angle, after which we will know the linear vertical size of the cylindrical lens and the vertical size of the slide equal to it. Knowing the width of the slide, which was originally laid down in the design of the scanning system, we can calculate the degree of horizontal compression of the captured image. The compression process is performed on a computer using a program specially created for this. Printing should be done on a transparent material and on a printer with the highest possible resolution. For example, at a resolution of 1440 άρί (dots per inch), 2268 elementary bands will be formed on a slide width of 40 mm, which is considered good for a movie image. You can use a higher resolution printer, such as 2880 άρί. Then it is possible to halve all sizes of the optical elements of the advertising device (except vertical), including the width of the slide. In this case, the image compression ratio will increase by 2 times. You can take the path of further reducing the horizontal dimensions of the light box, if you are satisfied with the lower horizontal resolution. The horizontal resolution (maximum number of distinguishable elementary bands) also depends on the ratio of the linear horizontal size of the observed image to the width of the slit of the shutter. For example, with an image width of 1330 mm and a slit width of 0.5 mm, the resolution is 1330: 0.5 = 2660 elementary bands. If you do not pursue the goal of such a good horizontal resolution, then you can increase the size of the slit, so that we get a gain in image brightness.

As mentioned above, the role of a slide with an image can be successfully performed by a transparent LCD display, onto which a fixed frame of an animated plot corresponding to the order of its location in the general system will be broadcast. Broadcasting of all motion pictures for the corresponding light boxes can be carried out from the metro station using computers equipped with a program specially created for this. In this case, the process of replacing the video will be greatly simplified and cheaper. The LCD displays themselves must comply with the parameters of the image being created: have a pixel structure in accordance with the required resolution, a geometric shape identical to the calculated dimensions of the slide carrying the compressed image. The process of transferring the proposed system to LCD displays will not require significant structural changes in advertising devices, but it will be necessary to specifically establish the production of such displays. Economically, this will be justified by the fact that the animation system will become more widespread, and LCD displays, due to their undeniable convenience in use, will sooner or later displace film-based slides.

Industrial applicability

The invention will find wide application in the field of advertising, in the form of a moving image in the subway and other places. It is not laborious to manufacture. The production of advertising animation devices according to the invention is possible in the conditions of optical-mechanical sections of industrial enterprises.

This description and examples are considered as material illustrating the invention, the essence of which and the scope of patent claims are defined in the following claims, a combination of essential features and their equivalents.

Claims (4)

CLAIM 1. An advertising animation device containing light boxes mounted in a tunnel along a train’s track with a scanning system of horizontally compressed images of individual paintings, representing the phase of movement of the general plot, using a vertically mounted narrow light source and a mirror reflector, the system scanning an image of a single plate with a film frame is located between the light source and the viewer, characterized in that the system is equipped with a cylindrical a lens with a slit shutter installed in the lens along its axis, and the center line of the slit of which coincides with the axis of the lens, behind the lens at the focal distance there is a plate with a film frame, which is an equal part of the cylindrical surface along the lens length, the center of the radius of curvature of which coincides with the lens axis while the light source is installed in parallel with the axis of the lens and the plate, and the mirror reflector has the shape of an ellipse arc, while the reflector is made and positioned so that the reflected light flux from the source that focused on the central axis of the lens passing through the plate from the image film frame. 2. The device according to claim 1, characterized in that the plate with the image is made in the form of a film slide with a geometrically modified, narrowed in width, image of one frame of a reproduced movie scene or an elastic, transparent liquid crystal display with - 6,026,222 by the size and shape of the film slide onto which a fixed frame of an animated plot is broadcast using a computer program. 3. The device according to claim 1, characterized in that the lens is made of an optically transparent material, for example glass or plastic, or in the form of a cylindrical tube of a transparent material filled with a liquid, for example water or a mixture of transparent and colorless liquids. 4. The device according to claim 1, characterized in that when the interval of placement of light boxes on the tunnel wall relative to each other is less than 0.3 m, several image scanning systems are preferably installed in each light box, and with an interval of 0.7-1.0 m and more than one image scanning system is preferably placed in a separate light box.