RU2141736C1 - Device for storing image or code information displayed on screen - Google Patents

Abstract

FIELD: computer engineering. SUBSTANCE: device has storing layer, which is made from photo sensitive material, which can be attached to monitor surface by means of adhesion layer provided on monitor surface. Photo sensitive layer is applied over said carrier layer and is active on monitor surface only in specific regions which are separated from each other. In addition invention specifies hardware mechanism for code transmission. EFFECT: increased definition of information displayed on screen. 14 cl, 4 dwg

Description

 The invention relates to a device for storing image information, in particular, a code displayed on a part of the area of a monitor containing a storage medium of photosensitive material that can be attached to the surface of the monitor using an adhesive layer on the surface of the monitor.

 A device of this type is known from German patent application P 4312185.3. The invention described in this application aims to provide a device by which any kind of television program can be made more interesting by involving the viewer, and by which the television company can obtain information regarding the number of viewers.

 Examples of the use of a device of the type described are given in the German patent application cited.

 Technically, the problem associated with this device is that the information displayed from the television screen is not clear due to the thickness of the glass tube (picture tube), so in some cases the information displayed cannot be stored in absolutely clear form on a photosensitive the material.

 It is an object of the present invention to provide a device for storing image information displayed on a part of a monitor area so that information displayed on a screen can be stored on the photosensitive material in the most clear possible way or so that it can be recognized as best as possible.

According to the invention, this problem is solved by the fact that the photosensitive material is applied to the carrier medium indicated by the contour and is active on the surface of the monitor only in special areas separated from one another. This is achieved by the fact that
- a masking or aperture layer, in particular, an aperture diaphragm layer that causes a focusing effect, is applied to the surface of the medium of the medium facing the monitor and allows light to penetrate into the active areas and does not allow to penetrate into the areas lying between the active areas, and / or
- photosensitive material is applied only to active areas of the carrier medium.

 The creation of active and inactive areas according to the invention ensures that the light emitted by the monitor throws the storage procedure into the active areas of the photosensitive material, which are separated from each other by inactive areas.

 A feature of the invention, according to which the photosensitive material is applied to the carrier medium indicated by the contour and is active from the monitor side, includes all possible embodiments of the carrier medium and photosensitive material, in which the light coming from the monitor can transfer the storage process to the photosensitive material from region to region, that is, photosensitive material can be applied to the surface facing the monitor, as well as, for example, when using transparent media — on the side where the media is facing away from the monitor.

 Since the individual active regions are separated from each other by inactive regions in each case, and are spatially separated, it is guaranteed that each region of the photosensitive material intended for storing information actually only receives light intended for this region, and reception of light information is prevented. intended for neighboring areas through inactive areas. Thus, a clear image can be obtained in all active regions of the photosensitive material, which are associated with the corresponding translucent regions of the masking or diaphragm layer.

 When transmitting a program, a symbol is displayed on the screen, the geometry of which is selected so that only certain areas of the photosensitive material are exposed. By assigning special numbers to active areas (for example, from 6 to 12), special codes can be displayed on the screen, in particular codes having from two to three different levels, brightness, which can be stored in photosensitive material with a code corresponding to a special arrangement of light and dark areas in the transmitted sign. Using a specific arrangement of bright areas, only the corresponding opposite active regions of the photosensitive material are exposed on the screen.

 In this way, it is possible, for example, when evaluating the storage device, to determine what type of program the viewer was watching, providing a special character of the specified type associated with this program. In the described way, the code that characterizes the program can then be stored in photosensitive material and, therefore, it can be checked whether the storage device was fixed on the screen during the broadcast of the program.

 In a possible embodiment, the device uses a non-photosensitive carrier material, for example a foil, on which a photosensitive material is applied only in those areas that are designed to store image information. These regions according to the invention are active regions which are separated from one another by inactive regions and on which no photosensitive material is applied.

 In this case, the advantage is that a relatively small amount of photosensitive material is required, since it is applied only to active regions of the carrier medium. Thus, the cost can be reduced.

 When using a masking or diaphragm layer, the translucent areas of the masking or diaphragm layer mark active areas on the photosensitive material on which image information can be stored. By this means, light can reach the photosensitive material only through the light-transmitting areas, while it is possible that the available areas of the photosensitive material, which are covered with light-tight areas, cannot be exposed.

 It is advantageous that when using a masking or aperture layer, the photosensitive material is specially applied only to those areas that are designed to store image information, since in this case the manufacturing cost can also be reduced.

 The masking or diaphragm layer may consist of at least a opaque material, for example paper, card, cardboard or plastic, or it may be applied by a coating method to a carrier medium.

 The clarity of the stored image can be enhanced by the fact that the mask or iris layer is formed so that a focusing effect is achieved.

 To this end, when using a masking or aperture layer having a certain thickness, light-transmitting areas can be formed by cutting, for example, an aperture or slotted aperture. In particular, it is possible to use a plurality of aperture or slit diaphragms, preferably from 3 to 500, substantially circular cut openings forming individual aperture diaphragms.

 In a preferred embodiment, the openings or active regions are regularly distributed around the center point of the mask or diaphragm layer.

 The thickness of the diaphragm layer should be selected depending on the sensitivity of the photosensitive material, the size of the holes on the diaphragm layer and / or the sharpness of the image, which should be stored and displayed on the surface of the screen. In this regard, the diaphragm layer can be thinner, the more sensitive the photographic material or the smaller the holes available on the diaphragm layer.

 A problem in the context of the invention is that the glass tube of the screen has a certain thickness, which leads to the fact that the image formed on the inner surface of the glass tube is not clearly displayed on the outer surface of the glass tube. In order to compensate for this lack of clarity, a diaphragm layer is formed that focuses the image on the photosensitive material. In this case, the focusing effect should be the stronger, the thicker the tube of the kinescope, which is why the thickness of the diaphragm layer can be less, the thinner the thickness of the tube.

 In domestic use, the thickness of the diaphragm layer is approximately 5 mm.

 For faster and more economical manufacture of the device, it is recommended that the device be made of various flat layers. For example, in one embodiment, only a mask or diaphragm layer and an adhesive layer can be applied to the photosensitive film. Thanks to this device for storing images with a flat design can be manufactured while saving space, and thus can be transported and sold at a cost-effective way.

 The storage medium may be formed in the form of a round disk, but may also be of other necessary shape, for example round or polygonal, in particular rectangular, hexagonal, octagonal. For example, you can give the storage device the form of the logo of a television company or another form typical for a specific business.

 From the point of view of technical manufacturing, the advantage is that the external contour of the masking or diaphragm layer corresponds essentially to the external contour of the medium carrier.

 A photosensitive material is used, which consists of substances that change the visibility without adding a developer when exposed to light, so that the developing process, which is usually carried out after exposure, can be omitted.

 Photochromic substances are preferably used. They differ in that they take on a specific color when irradiated with ultraviolet light and become transparent when irradiated with visible light.

 Before the storage procedure, photochromic material is irradiated with ultraviolet light) in order to then subsequently save the image or symbols that reflect or transmit visible light. Between irradiation with ultraviolet light and the storage procedure, it must be ensured that the photosensitive material is not irradiated with visible light or irradiated with visible light only for a very short time. To this end, the preserving material can be applied to a surface separated from the adhesive layer by a lightproof layer, and can be fixed using the adhesive layer on a translucent carrier card, for example, a postal card.

 The exposure time during which the image is stored on the photochromic layer is approximately 30 minutes, but it varies depending on the photochromic substance used and the brightness of the transmitted image.

 When the photosensitive layer consists of several photochromic substances, which respectively respond to visible light with different wavelengths, color images can also be stored in the storage device.

 The advantage of using photochromic substances is that the photosensitive material can be reused by simply irradiating it with ultraviolet light after exposure.

 In a preferred embodiment, the carrier medium into which the photosensitive layer is introduced is applied to a surface separated from the surface of the monitor by a reflective layer, in particular a shiny, white and / or metallic reflective layer, which reflects rays penetrating through the photosensitive layer or a transparent medium of the carrier back to the photosensitive layer. This allows a more intense exposure of the photosensitive layer and thus reduces the exposure time.

 The aluminum or silver layer is preferably deposited by vapor deposition on the surface of the medium of the carrier or photosensitive material, remote from the surface of the monitor.

 An adhesive layer that is applied to the side of the masking or diaphragm layer remote from the medium of the carrier is formed as a self-adhesive layer that can be coated with a removable protective film before use in the device. In this form, the storage device can be sold and, moreover, the viewer can easily handle it.

 It is not necessary, however, that the adhesive layer be self-adhesive, it can be designed so that the storage device simply adheres to the screen by electrostatic forces.

 It is advantageous that the layer that absorbs visible light, in particular, the black layer, is applied to the side facing the monitor. This is done in order to avoid distorting reflections and the associated erroneous exposures. To this end, the adhesive layer can be made, for example, of a material that absorbs visible light.

 The storage device may be provided with an opaque layer on the side remote from the monitor. Any desired text or desired symbol can be printed on this layer in a manner visible to the viewer, and can be visible to the viewer as long as the storage device is printed on the screen. Thus, the side of the storage device remote from the monitor can be used as an advertising surface.

 The photosensitive material may be designed to store code elements with different steps or levels of brightness, in particular with two or three different levels of brightness.

 In addition, it is possible to make a memorable medium frequency selective so that it only responds to specific wavelengths, for example, a specific color wavelength. This allows you to save color images.

 Due to the fact that it is possible to store several levels of brightness or multiple colors, the number of different codes that can be stored is significantly increased.

 In order to simplify the positioning of the preservation medium, at least one, and in particular three or four, reference marks distributed around the periphery of the medium of the medium or the masking or aperture layer can be applied to the monitor, they must be aligned with one or more marks on the monitor during attaching a storage medium to the monitor.

 The reference marking can be formed using the line of the external contour of the carrier medium and / or the mask or diaphragm layer, and then indicated by a line that is not centrally symmetric so that the storage medium can be attached to the screen with a certain orientation.

 Further simplification of the attachment procedure can be achieved when a central hole, in particular a circular hole, is defined in the central part of the mask or diaphragm layer.

 Since the size of the character to be remembered by this medium depends on the size of the corresponding monitor, the size of the recording medium must correspond, at least in some limits, to the size of the monitor.

 To this end, a layered structure consisting of a masking or diaphragm layer and a photosensitive material or carrier medium can be formed from an essentially essentially circular region and at least one annular region that concentrically surrounds the latter, the circular and annular regions being separated from each other . In this case, the hole or active region in the annular region is associated with each hole or each active region in the circular region. Preferably, the corresponding holes or active areas are essentially in a straight line, which is drawn from the center point of the masking or diaphragm layer.

 When using the storage medium thus formed on the smaller screen, the circular region is separated from the annular region and attached to the screen without the annular region. When using the storage medium on a larger screen, either the entire storage medium consisting of a circular region and an annular region or only an annular region separated from the circular region is used.

 When the storage medium is to be used for screens with very different sizes, a larger number of annular regions concentrically arranged relative to one another can be used.

 When the storage medium is divided into a circular region and at least one annular region, it is advantageous that both the circular region and the annular region are provided with reference marks so that one circular region can be positioned on the monitor without problems.

 At least one lens, for example a plastic lens, which is preferably formed as a Fresnel lens, can be used between the screen and the storage medium or between the adhesive layer and the carrier medium. A lens of this type can be easily integrated into the multi-layer structure of the storage device.

 The lens can serve for additional focusing of the character, fuzzy display on the screen so that it is clearly displayed on the storage medium. If necessary, a design consisting of many lenses can also be applied.

 The storage device according to the invention can also be made in such a way that a developer that makes visible the information of the stored image is embedded in the storage device or so that the information of the stored image can subsequently be developed by the developer layer or the developing liquid, which can be brought into contact with the storage device.

 It is especially advantageous when the storage device is fixed at the time of purchase by the user on a card or paper medium, card, cardboard or multilayer card or cardboard, which, in particular, has the format of a postal card. In this case, the storage device can be sold in the usual way, and at the same time, the viewer has a carrier such as a soil card onto which the user can reconnect the storage devices after exposure and send them back to the television company. Therefore, it is advantageous when the carrier card, including the storage medium, has a weight less than or equal to 50 g, since in this case only a small postage is paid.

 In addition, it is advantageous that the storage device is attached to a card the size of a postcard with the possibility of separation from it by separating the adhesive layer.

 In this case, the protective film covering the sticky layer may be absent. The adhesive layer can also be reused after exposure of the storage device for attaching the storage medium to a carrier card the size of a postal card.

 You can place more than one storage device on a storage card.

 To simplify the removal of the storage medium, there are service recesses on the carrier card.

 A method has also been developed for the technical transmission of a code that can be displayed on a part of the area of a television screen, which contains several code elements with different brightness levels or colors and which can be stored on an optical storage medium of the described type attached to a television screen.

 In order to provide the ability to store the codes shown on television screens of various sizes on a storage medium of the same size, the codes have at least a centrally symmetrical shape.

 Preferably, the code has a circular shape with codes transmitted to code elements that are in the form of a circle sector and are attached to one another.

 In addition, it is advantageous when specific code elements of the code can be transmitted sequentially one after another in a television program so that the viewer never sees the complete code on the screen, which prevents the danger of falsification.

 In addition, it is advantageous when there is no need to transmit the code with a special television program, it is selectively included in it by means of teletext so that only those viewers call the code that use the storage device according to the invention.

The invention is further explained in the description of the preferred embodiment with reference to the accompanying drawings, in which:
FIG. 1 shows a screen with a storage device according to the invention;
FIG. 2 is a plan view of a carrier card with a storage device according to the invention;
FIG. 3 is a section along line AA in FIG. 2 according to the invention;
FIG. 4 is a code transmitted in accordance with the method according to the invention.

 In FIG. 1 is a front view of a monitor or television screen 1. In the upper left corner of the screen is shown a disk-shaped storage device 2 that is directly attached to the screen and covers part of the area of the television image.

 On the. FIG. 2 shows a carrier card 3 for six storage devices. In the same way, more or fewer storage devices can be placed on the storage card.

 Card-carrier 3 can be made of cardboard and have the format of a postal card. In such a form, the storage devices 2 can be sold in a particularly advantageous way, since the carrier card 3 can be used, on the one hand, as a package for selling the storage device 2 and, on the other hand, for returning the exposed storage device 2.

 The storage device 2, which has a thickness of approximately 5 mm, is inserted into the cutouts of the storage card 3, which coincide with the shape of the storage device 2. Unwanted separation of the storage device 2 from the storage card 3 is prevented, for example, by a partial engagement between the edge region 4 of the storage device 2 and corresponding hole. The storage devices 2 can also be attached by means of their sticky layer to the card 3.

 In order to facilitate removal of the storage device 2 from the carrier card 3, auxiliary recesses are provided in the carrier card.

 The storage devices 2 consist of an essentially circular inner region 6 and an annular region 7 which concentrically surrounds the circular, the circular region 6 and the annular region 7 being preferably connected by means of friction so that they can be separated from each other if necessary.

 The annular region 7 has 8 holes through which light can pass to the photosensitive material located on the storage devices 2. Eight holes 8 are evenly distributed around the periphery of the annular region 7.

 One hole 9 in the circular region is associated with each hole 8 of the annular region. In this design, the associated holes 8, 9 are on a straight line drawn from the center point 10 of the storage device 2.

 In the annular region 7 there are four marks 11, which are evenly distributed around the periphery of the storage device 2 and serve for positioning on the screen 1. Three of these reference marks 11 are in the form of triangular recesses, and one of the marks 11 also has the shape of a protruding triangle.

 The annular region 7 is provided with corresponding reference marks 12.

 At the central point 10 of the storage devices 2 there is a circular central opening 13, which can additionally serve for positioning.

 In order to prevent the exposure process carried out by the monitor 1 from being intentionally tampered with by an intentionally used light source or to make it more difficult, at least one security opening 24, 25 providing security against tampering can be located on the memory 2 or masking or diaphragm layer so that the active region formed by this hole 24, 25, providing security against counterfeiting, received light from at least two code elements that could t be displayed on the monitor. If one of these two code elements is dark and the other is light, then the average brightness value between the exposure of the dark code element and the exposure of the light code element will be stored in the photosensitive area associated with the security hole 24, 25 against counterfeiting.

 It is much more difficult to fake this average value than to fake only one dark or one light exposure level, whereby safety against counterfeiting is increased.

 In one embodiment, six holes 24 are made in the annular region 7 to provide security against counterfeiting, and six holes 25 for security against counterfeiting are made in the circular region 6.

 As already noted above, the storage device 2 can be placed with the possibility of removal on special areas of the card carrier 3 before using them. For exposure, storage devices 2 are removed from the carrier card 3. After exposure, the storage devices 2 can be reinserted into the carrier card 3 and sent together with the carrier card 3 in the form of a postal card to a television company.

 The address of the television company is preferably printed on the non-informative back side of the carrier card 3.

 The carrier card 3 may also be provided with through holes, into which or above which the memory devices can be inserted after they have been exposed by the side provided with the adhesive layer, for later viewing through these holes from the back of the carrier card. This facilitates the evaluation of the exposed storage devices, since they can, for example, be examined by an image processing system without being removed from the storage card. In order to avoid further exposure of the storage devices in such a carrier card after they have been applied to the carrier card, the latter in this case is provided on the back side with a lightproof element, for example, a removable foil or card material that can be folded. The transparent foil may preferably be applied between the opaque material and the adhesive layer on the storage devices, at least in the region of the openings. In addition, the carrier card may be provided on the front surface onto which the storage devices are glued with at least one additional layer that protects the storage elements on the storage devices from damage or closes them.

 Other embodiments of the carrier card are possible, for which it is guaranteed that the exposed storage devices are not exposed to any additional amount of incident light after it is exposed, and it is not possible to simply read image information stored in the storage elements on the storage devices.

 In FIG. 3 shows a section along line AA in FIG. 2 of the annular region 7 of the storage device 2 before being displayed on the screen.

 The storage device 2 is made detachable with a transparent or translucent adhesive layer 14, active on the screen side, coated before using the storage device 2 with a protective film 15, which can be removed by the user from the adhesive layer 14 in the direction shown by the arrow. The storage device 2 can then be attached to the screen with an adhesive layer 14 and can be exposed after removing the protective film 15.

 The adhesive layer 14 is followed by a diaphragm elephant 16, which is provided with through holes 8, as is the adhesive layer 14. The diaphragm layer 16 is made of opaque material so that light can only pass through the diaphragm layer 16 in the region of the hole 8. When the diaphragm layer 16 or holes 8 are the same thickness, a focusing effect can be achieved in accordance with the principle of the aperture diaphragm. For this, the thickness of the diaphragm layer 16 or holes 8 should be selected depending on the sensitivity of the photosensitive material and on the thickness of the glass tube of the tube.

 Thus, a sharper image displayed on the screen can be achieved on the photosensitive layer 17, which is connected to the diaphragm layer 16 on the side remote from the adhesive layer 14.

 The photosensitive layer 10 is then deposited on the side remote from the diaphragm layer 16 by the reflection layer 18 to reflect the light emitted by the monitor. This reflective layer, in particular, may be metallic and reflects the light emitted by the monitor and passing through the photosensitive material 16 back to the photosensitive material 17.

 All layers are preferably made of flexible material, which, in particular, facilitates the release or removal of the storage device from the screen.

 In FIG. 4 presents code 19. which can be transmitted using the proposed method and which is suitable for the exposure of the storage device 2.

 Code 19 is centrally symmetrical and has a substantially circular shape.

 Code 19 is split into 8 code elements 20, 21, each of which has the shape of a circle sector.

 In the depicted example, special code elements 20 are shown in light, while the remaining code elements are shown in dark. Through various arrangements of the light and dark areas, as well as by changing the ratio between the number of light and dark areas, a total of 256 different codes can be transmitted or represented using 8 code elements 20, 21 in the form of a circle sector.

 The storage device 2 is located above the code 19, on the screen 1 so that in each case one hole 8, 9 is located above each code element 20, 21, through which the information light or dark contained in the code element 20, 21 is transmitted to the photosensitive material 17 storage device 2.

 Since the code elements 20, 21 are in the form of a circle sector, the correct exposure of the storage devices 2 is always ensured when the holes 8, 9 are located above the associated area in the form of a sector of the code circle 19. Thus, a variable arrangement of the holes 8, 9 in the entire code area is possible an element 20, 21 having the shape of a circle sector, at least when the area of the holes 8, 9 is smaller than the area of the code element 20, 21. To memorize the codes 19 represented by the different sizes of the television screens 1, a uniform and constant size can t be stored in the memory 2. Thus, the memory 2 may be used in a range of different screen sizes. If this range is exceeded, then the storage device 2 can be split into two areas 6, 7 of different sizes.

 The region 22 in the form of a point is transmitted to the central point of the code 19, over which, for example, the central hole 13 can be positioned (Fig. 2) and which can change its color during the exposure time. Color change may occur due to the full expiration of the exposure time.

 At the beginning of the transmission of the code 19, the regions 23 in the form of arrows can be transmitted distributed around the periphery, for example, into three positions. These arrow-shaped regions 23 serve to position the storage device 2 on the screen 1. The reference marks 11, 12 in the form of recesses are aligned with the arrow-shaped regions 23.

 More or less code elements can be connected to one code, or a plurality of brightness levels or colors can be transmitted to one code element. In particular, when transmitting a code with three different brightness levels “bright”, “medium” or “dark”, at least one special element with a level of “medium” can be transmitted so that it is transmitted for approximately half of the total exposure time as the level is "bright", and during the remaining exposure time - as a "dark" level. In this way, they increase security against falsification, since the viewer, when examining the displayed code, cannot judge which code element ultimately causes the value "average" on the storage device.

Claims (14)

 1. A device for storing image information, in particular code displayed on a part of the area of the monitor, containing a storage medium of a photosensitive material that is attached to the surface of the monitor by means of an adhesive layer located on the surface of the monitor, characterized in that the photosensitive material is applied to a limited contour medium carrier and is active on the surface of the monitor only in areas separated from each other by areas in which the photosensitive material does not show t Activity.  2. The device according to p. 1, characterized in that the masking or diaphragm layer is deposited on the surface of the carrier medium adjacent to the monitor, and is permeable to light in the active areas and not permeable to light in the areas between the active areas and / or photosensitive material applied only to the active areas of the carrier medium with a masking or diaphragm layer consisting of a lightproof material having at least one hole forming a translucent region.  3. The device according to p. 1 or 2, characterized in that it contains many holes, essentially round in shape, forming individual aperture diaphragms and / or active areas located at the same distance around the center point of the mask layer or the diaphragm layer, the thickness the aperture layer is about 5 mm and is selected depending on the sensitivity of the photosensitive material, the size of the holes made in the aperture layer, and / or the clarity of the image, which should be stored and displayed on and the surface of the screen, and the masking or aperture layer consists of paper, or cardboard, or plastic and is a laminated photosensitive material or its carrier medium.  4. The device according to claim 3, characterized in that the number of holes is mainly 3 to 500.  5. The device according to one of claims 1 to 4, characterized in that it contains at least one reference mark located on the periphery of the carrier medium or masking or diaphragm layer, which are intended for positioning on the monitor, while the external contour line of the medium the carrier and / or the masking or diaphragm layer is an off-center symmetrical line, and the marking is formed by at least one part of the outer contour line of the carrier medium and / or the masking or diaphragm layer, and a layered structure consisting of masking or diaphragm layer and the photosensitive material, or the carrier medium is formed from a circular inner region and at least one annular area concentrically surrounding the circular, the circular and annular areas are separated from each other.  6. The device according to claim 5, characterized in that it contains three or four reference marks located on the periphery of the carrier medium.  7. The device according to one of claims 1 to 5, characterized in that the hole or usable area in the annular region is associated with each hole or each active region in the circular region with associated openings or associated useful regions, each located essentially on a straight line drawn from the center point of the masking or aperture layer, while the circular region, as well as the annular region are provided with reference marks, and the masking or aperture layer has a substantially circular or polygonal shape and the central point of the masking or aperture layer has an additional circular central hole.  8. The device according to claim 7, characterized in that as a polygonal shape, a rectangular, or hexagonal, or octagonal shape is used.  9. The device according to one of claims 1 to 8, characterized in that at least one hole designed to protect against counterfeiting is also applied to the masking or diaphragm layer so that the active region formed by this hole providing protection against counterfeiting, receives light from at least two code elements that can be displayed on the monitor, while the outer contour of the masking or aperture layer corresponds essentially to the outer contour of the medium of the medium, and the photosensitive material consists of a substance, preferably a photochromic material, which visually changes under the influence of light without adding a developer and is intended for storing code elements of various brightness levels, in particular two or three different brightness levels, and for storing information of a color picture, the photosensitive material containing many photochromic substances that are sensitive to light of various wavelengths.  10. The device according to one of claims 1 to 9, characterized in that the photosensitive material is sensitive to ultraviolet and visible light, and the stored image is removed by irradiation with ultraviolet light, while the reflective layer is deposited on the surface of the carrier medium to a side remote from the surface monitor, and reflects the light emitted by the monitor back onto the photosensitive material, with the aluminum or silver layer deposited by vapor deposition on the surface of the medium of the carrier or photosensitive material removed about t of the surface of the monitor, and the adhesive layer is placed on the side of the masking or diaphragm layer remote from the carrier medium, absorbs visible light and is applied to the side facing the monitor, at least one plastic lens is placed between the adhesive layer and the carrier medium.  11. The device according to one of claims 1 to 10, characterized in that the reflective layer is selected from the group consisting of shiny, white and metallic layers.  12. The device according to one of claims 1 to 11, characterized in that at least one storage medium is mounted on a carrier of paper, or cardboard, or multilayer cardboard by means of an adhesive layer, while the carrier has auxiliary recesses to simplify the removal of the storage medium and the medium has a postcard format and weight, including the weight of the storage medium, less than or equal to 50 g.  13. A method for transmitting a code to be presented on a part of the area of a television screen, which consists of a plurality of code elements with different brightness levels and which is stored in a storage medium attached to the television screen, characterized in that the code is transmitted in a centrally symmetrical form for storing codes displayed on television screens of various sizes in a memorable medium of the same size, the code being transmitted essentially in a circular form and / or code elements having the form of sects ora circle.  14. The method according to item 13, characterized in that in addition to the code transmit at least one mark for positioning the storage medium on television screens, special code code elements are transmitted in time sequence when transmitting a code with three different levels of brightness "bright", " medium "or" dark ", for at least half of the total exposure time at least special code elements with a level of" medium "as a level of" bright "are transmitted, and during the remaining exposure time, as a level of" th "code transmitted in addition to at least one marker, the color or brightness of which is changed after a predetermined transmission time to indicate the end of the exposure time storage medium, the code is transmitted via teletext, which can optionally be included with the television program.

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