RU2346325C2 - Product counterfeit protection method and device for its implementation - Google Patents

Abstract

FIELD: physics, processing of images.

SUBSTANCE: invention deals with product counterfeit protection devices and provides for falsification prevention. Method envisages imaging of an info label integrated in a bulk of optically transparent material through its structural modification as a result of thermal treatment by means of radiation energy concentration at a certain point of the material bulk, the radiation energy concentration point translocation within the material bulk and modulation of the radiation power in the course of the above translocation as per the algorithm assigned. The info label real image is pre-encoded with the info label imaging inside the optically transparent material bulk proceeding in the coded form, the technique providing for feasibility of its real form decoding for eventual visual identification. To provide for the method practical implementation one proposes two design variants of a product counterfeit protection device as well as the optical coder and decoder fabrication method.

EFFECT: improved product unlawful reproduction protection.

6 cl, 7 dwg

Description

The invention relates to methods for protecting products of artistic or material value from falsification, and can be used to prevent falsification in the market for trade in these products.

Known methods of protecting valuable products from counterfeiting consist in applying labels to the surface of the product in the form of a signature, sign, graphic image or other information, consisting, for example, in giving the material of the label certain properties known only to the manufacturer of the label. However, the labels obtained in the first two ways are easily reproducible, which contributes to their unauthorized use and, as a result, to fake the product. The third type of labeling is more informative and can be implemented in the method of marking products using the photolithography process, according to which to obtain an image on the surface of the product it is covered with a layer of photoresist and exposed under a flexible negative, which is applied to the surface of the product before exposure [Aut. testimonial. USSR No. 406978, B41M 1/40, 1971].

However, when using this method of marking, the label is very loosely bound to the product material and can be quite easily separated from its surface. In addition, the mark pattern can be reproduced on the product by other persons, which creates the prerequisites for counterfeiting the mark. Due to the noted drawbacks, this method did not find application in the technology of protecting valuable products from counterfeiting, for which the information in the label allows you to reliably distinguish between products.

A more promising way to protect the product from counterfeiting by giving the tag material certain properties that are known only to the tag manufacturer. A known method of marking products, according to which on the surface of the product is applied pre-made label of a dielectric material with structural inhomogeneities formed within a given contour. These structural inhomogeneities are volumetric systems of capillaries that arise in a dielectric when it is simultaneously exposed to a temperature field and an electron beam. The label can be attached to the product, for example, by means of an adhesive joint [Auth. testimonial. USSR No. 1757864, B25H 7/00, 1992].

Since the characteristic region of heterogeneity, limited by a given contour, cannot be repeated, the known method of marking the product reliably protects the mark from forgery. However, in industrial implementation, this method requires the manufacture of a large number of tags and compilation of a data bank for them to identify products. This significantly complicates the technology of product labeling and makes it necessary to use expensive equipment. In addition, the label can be quite easily separated from the product and transferred to another product, which will lead to the impossibility of its identification.

The closest in technical essence and selected for the prototype is a method of marking glasses, mainly triplex, which includes obtaining an image inside the volume of an optically transparent material by changing its structure by heat treatment due to the concentration of radiant energy at a certain point in the volume during sequential movement of the material according to a given pattern. Glass marking in the form of a different code (digital, alphanumeric, alphanumeric or other) is carried out at the glass-polymer interface by pulsed laser radiation [RF Patent No. 2024453, C03C 27/12, 1994].

Of the devices closest in technical essence and selected for the prototype, there is a device for protecting products from optically transparent materials from falsification, including a laser, a laser beam focusing lens with a mechanism for changing its focal length, a computing unit, a video monitor, a movable mirror, a drive moving the mirror [PCT Application No. 2004000749, С03С 23/00, 2000].

Technical solutions both for the prototype for the method and for the prototype for the device allow you to create images of information labels inside the volume of an optically transparent material of products, including in the form of a different code. The label cannot be separated from the product and transferred to another product, which ensures reliable identification.

A disadvantage of the known technical solutions is that the image of the label itself, including the image of the code, can be faked by copying and reproducing inside the volume of an optically transparent material of a falsified product on similar equipment.

The technical result of the invention is the creation of such a method of protecting products from counterfeiting and a device for its implementation, which would provide maximum difficulty in identical copying of the image information label due to insufficient information necessary for its implementation.

The technical result is achieved by the fact that the method of protecting products from counterfeiting involves obtaining an image of the information label inside the volume of an optically transparent material by changing its structure by heat treatment due to the concentration of radiant energy at a certain point in the volume of the material, moving the concentration point of radiant energy inside the volume of the material and changing the radiant power energy for a given movement according to a given algorithm.

According to the invention, the real image of the information label is preliminarily converted into a coded form, and inside the optically transparent material, the image of the information label is formed in encoded form with the possibility of its decoding into a real form for subsequent visual identification.

As a real image of an information label, images of real objects, company marks, and images of various codes can be used. When used as a real image information label images of different codes provides two-stage coding. At the first stage, product information, as follows from well-known technical solutions, is encrypted with the content of the code itself. At the second stage, as proposed in the claimed technical solution, the image of the code itself is executed in encoded form.

To implement the method, there are two variants of a device for protecting products from counterfeit.

According to the first embodiment, the device includes a laser, a laser beam focusing lens with a mechanism for changing its focal length, a computing unit, a video monitor, a movable mirror, a mirror moving drive.

In addition, the device further includes an information label image forming lens, an optical radiation receiver, an electronic information label image encoder and an identifier including an identifier lens, an identifier optical radiation receiver, an electronic decoder, an electronic microdisplay and an eyepiece.

The output of the information label image forming lens is optically connected to the optical input of the optical radiation receiver, the electrical output of which is electrically connected to the input of the electronic information label image encoder. The output of the electronic information mark image encoder is electrically connected to the input of the computing unit, the first, second, third and fourth outputs of the computing unit are electrically connected respectively to the input of the video monitor, the input of the mirror moving drive, the input of the mechanism for changing the focal length of the laser focus lens and the laser control input. The laser optical output is optically coupled to the optical input of the laser beam focusing lens. The optical output of the focusing lens of the laser beam through the reflective surface of the mirror is optically connected with the installation area of the workpiece. The identifier lens is optically coupled to the input of the identifier optical radiation receiver. The output of the optical radiation receiver of the identifier is electrically connected to the input of the electronic decoder. The output of the electronic decoder is electrically connected to the input of the electronic microdisplay, and the screen of the electronic microdisplay is optically connected to the eyepiece.

According to the second embodiment, the device for protecting products from counterfeiting includes a laser, a laser beam focusing lens with a mechanism for changing its focal length, a computing unit, a video monitor, a movable mirror, a mirror moving drive. In addition, the device further includes an information mark image forming lens, an optical information mark image encoder, an encoded image transfer lens of the information mark, an optical radiation receiver and an identifier including an identifier lens, an optical decoder and an eyepiece.

The output of the information label image forming lens is optically coupled to the input of the optical information label image encoder. The output of the optical encoder image information label is optically connected to the input of the lens transfer image information label. The output of the image transfer lens of the information label is optically coupled to the input of the optical radiation receiver. The output of the optical radiation receiver is electrically connected to the input of the computing unit, the first, second, third and fourth outputs of the computing unit are electrically connected respectively to the input of the video monitor, the input of the mirror moving drive, the input of the mechanism for changing the focal length of the laser focus lens and the laser control input. The laser optical output is optically coupled to the optical input of the laser beam focusing lens. The optical output of the focusing lens of the laser beam through the reflective surface of the mirror is optically connected with the installation area of the workpiece. The identifier lens is optically connected to the input of the optical decoder, and the output of the optical decoder is optically connected to the eyepiece.

The term "optically transparent material" in this application means a material that transmits rays of at least one of the ranges: visible, infrared or ultraviolet.

The information label material must, firstly, transmit radiation whose concentration inside the material volume when changing its power and when moving according to a given algorithm creates an information label image inside the material (the radiation creating the label image can, in principle, be not only optical), but secondly, to transmit optical radiation in order to realize the possibility of forming an image of an information label during its identification.

There may be various options. If the material transmits radiation in the visible wavelength range, such as glass, then, for example, an yttrium aluminum grenade laser with a radiation wavelength lying in the transparency region of the glass can be used, and a video camera can be used as a receiver of optical radiation of the identifier.

If the material does not transmit radiation in the visible range, but transmits radiation in the infrared wavelength range, for example, germanium, then a CO ₂ laser with λ = 10.6 μm can be used as a laser, and a thermal imager as an optical radiation detector.

The use of materials as information mark materials that are opaque to visible radiation and transmitting, for example, infrared radiation, is an additional and very serious degree of protection of products from counterfeiting.

The mark can be made directly in the product itself or pre-made and then "implanted" into the product without the possibility of dismantling. In the first case, the product should be completely made of optically transparent material. In the second case, the product can be made of optically opaque material, and the material of the information label itself should be optically transparent.

The optical encoder and optical decoder can be made in the form of fiber optic fibers with a fixed arrangement of optical fibers at their inputs, not identical to their fixed location at the outputs. The location of the optical fibers at the input of the optical encoder is identical to their location at the output of the optical decoder, and the location of the optical fibers at the output of the optical encoder is identical to their location at the input of the optical decoder.

An optical encoder and an optical decoder can be manufactured as follows. The optical fibers of a piece of optical fiber at the ends are rigidly fixed in relation to each other using glue, for example using epoxy resin. Then, in the middle region of the length of the fiber optic fiber, the arrangement of the optical fibers with respect to each other is arbitrarily changed, and with this changed arrangement in the middle region of the segment of the optical fiber, the optical fibers are rigidly fixed to each other also with glue, for example also with using epoxy resin. Then the length of the fiber along the middle fixed area is cut into two parts. In this case, one part can act as an optical encoder, and the second part can be an optical decoder.

A device for protecting products from counterfeiting may further include a remote system for receiving, storing, processing and transmitting information about information labels and a means of communication with this system.

A system for receiving, storing, processing and transmitting information about information labels may include a transceiver, a correlator, a comparator, and a computer.

A means of communication with a system for receiving, storing, processing and transmitting information about information labels can be made in the form of a cell phone with an integrated camera, having a device for reading information about information labels made in the form of an optical set-top box.

If labels A are made in a material that does not transmit radiation in the visible range, but transmits radiation in the infrared wavelength range (germanium), then a thermal imager can be used as an optical prefix 28.

In this case, the output of the optical set-top box should be optically connected to the optical input of the built-in camera, the electrical output of the transceiver, respectively, is electrically connected to the first input of the correlator, the second input of which is electrically connected to the output of the computer, and the output is electrically connected to the first input of the comparator. The output of the comparator must be electrically connected to the electrical input of the transceiver, and the second input of the comparator is electrically connected to the source of the reference voltage.

The above features relate to a group of inventions related by a single inventive concept.

The industrial applicability of the invention is confirmed by the fact that it can be carried out in accordance with the proposed description and drawings based on known components using modern technological equipment.

The invention is illustrated by drawings,

where figure 1 shows a diagram of a device for protecting products from counterfeiting using an electronic encoder and an identifier circuit using an electronic decoder,

figure 2 is a diagram of a device for protecting products from counterfeiting using an optical encoder and an identifier circuit using an optical decoder,

figure 3 is a manufacturing diagram of an optical encoder and an optical decoder.

figure 4 - diagram of a remote system for receiving, storing, processing and transmitting information about information labels and means of communication with this system.

A device for protecting products from counterfeiting in the first (electronic) version (Fig. 1) includes a laser 1, a focusing lens of the laser beam 2 with a mechanism for changing its focal length 3. The device also includes a computing unit 4 with a keyboard 5 and a mouse 6, a video monitor 7, a mirror 8 arranged to move, a moving drive 9 of the mirror 8, an image forming lens of the information mark 10, an optical radiation receiver 11, an electronic image encoder of the information mark 12 and an identifier. The identifier includes an identifier lens 13, an optical radiation receiver of identifier 14, an electronic decoder 15, an electronic microdisplay 16 and an eyepiece 17.

If the material of label A transmits radiation in the visible wavelength range, for example glass, then, for example, a yttrium-aluminum grenade laser with a radiation wavelength lying in the transparency region of the glass can be used as a laser 1, and, as an optical radiation detector, identifier 14 can be used camcorder.

If the material of label A does not transmit radiation in the visible range, but transmits radiation in the infrared wavelength range, for example, germanium, then a CO ₂ laser with λ = 10.6 μm can be used as laser 1, and an identifier of optical radiation can be used 14 thermal imager.

The output of the image forming lens of the information label 10 is optically connected to the optical input of the optical radiation receiver 11, the electrical output of which is electrically connected to the input of the electronic image encoder of the information label 12. The output of the electronic image encoder of the information label 12 is electrically connected to the input of the computing unit 4, the first, second , the third and fourth outputs of the computing unit 4 are electrically connected respectively to the input of the video monitor 7, the input of the drive moving the mirror 9 , the input of the mechanism for changing the focal length of the focusing lens of the laser beam 3 and the control input of the laser 1. The keyboard 5 and the “mouse” 6 are connected to the control inputs of the computing unit 4. The optical output of the laser 1 is optically connected to the optical input of the focus lens of the laser beam 2. The optical output of the lens focusing the laser beam 2 through the reflective surface of the mirror 8 is optically connected with the installation area of the workpiece. The lens of the identifier 13 is optically connected to the input of the optical radiation receiver of the identifier 14. The output of the optical radiation receiver of the identifier 14 is electrically connected to the input of the electronic decoder 15. The output of the electronic decoder 15 is electrically connected to the input of the electronic microdisplay 16, and the screen of the microdisplay 16 is optically connected to the eyepiece 17.

The device for protecting products from counterfeiting in the second (optical) version (figure 2) includes a laser 1, a focusing lens of the laser beam 2 with a mechanism for changing its focal length 3. In addition, the device includes a computing unit 4 with a keyboard 5 and a mouse 6 , video monitor 7, mirror 8, made with the possibility of movement, moving drive 9 of the mirror 8, the image forming lens of the information mark 10, the optical radiation receiver 11, the optical encoder image information mark 18, the encoded transfer lens image information and ID tag 19. The identifier includes an identifier lens 13, an optical decoder 20, and an eyepiece 17.

The output of the imaging lens of the information label 10 is optically connected to the input of the optical image encoder of the information label 18. The output of the optical encoder image information of the information label 18 is optically connected to the input of the image transfer lens of the information label 19. The output of the image transfer lens of the information label 19 is optically connected to the input of the optical radiation receiver 11. The output of the optical radiation receiver 11 is electrically connected to the input of the computing unit 4, the first, second, third and even The grated outputs of the computing unit 4 are electrically connected respectively to the input of the video monitor 7, the input of the displacement drive 9 of the mirror 8, the input of the mechanism for changing the focal length of the focusing lens of the laser beam 3, and the control input of the laser 1. The keyboard 5 and the mouse 6 are connected to the control inputs of the computing unit 4 The optical output of the laser 1 is optically coupled to the optical input of the focusing lens of the laser beam 2, the optical output of the focusing lens of the laser beam 2 through the reflective surface of the optical mirror 8 and is associated with the installation zone of the workpiece. The identifier lens 13 is optically connected to the input of the optical decoder 20, the output of the optical decoder 20 is optically connected to the eyepiece 17.

The optical encoder 18 and the optical decoder 20 are made in the form of fiber optic optical fibers (Fig. 3) with a fixed arrangement of optical fibers 21 at their inputs, not identical to their fixed location at the outputs. The location of the optical fibers 21 at the input of the optical encoder 18 is identical to their location at the output of the optical decoder 20, and the location of the optical fibers 21 at the output of the optical encoder 18 is identical to their location at the input of the optical decoder 20.

The device for protecting products from counterfeiting additionally includes (figure 4) a remote system for receiving, storing, processing and transmitting information about information labels and a communication tool with this system.

The system for receiving, storing, processing and transmitting information about information labels includes a transceiver 22, a correlator 23, a comparator 24, and a computer 25. The communication system with a system for receiving, storing, processing, and transmitting information about information labels is implemented as a cell phone 26 with an integrated camera 27 and optical box 28.

The output of the optical set-top box 28 is optically connected to the optical input of the integrated camera 27. The electrical output of the transceiver 22 is electrically connected to the first input of the correlator 23, the second input of which is electrically connected to the output of the computer 25, and the output is electrically connected to the first input of the comparator 24, the output of the comparator 24 is electrically connected with the electrical input of the transceiver 22, and the second input of the comparator 24 is electrically connected to a source of a reference voltage (not shown in the drawings).

The method of protecting products from counterfeiting when using the electronic version of the device can be carried out as follows.

The image of the information label A is created using the image forming lens of the information label 10, from the output of which it is transmitted to the optical input of the optical radiation receiver 11. In the optical radiation receiver 11, which is based on a CCD matrix, the optical form of the image of the information label A is converted to electronic a form, which in the form of a signal of a video frame of a real image, for example, a code image, is transmitted to the input of the electronic image encoder information labels 12. Based on the signal a real video frame using a random number sensor, the microprocessor device of the electronic encoder 12 generates an encoded image of the video frame in which the location of the information pixels inside the line and between the scan lines is randomly changed. The encoded image of the information label A from the output of the electronic encoder image information label 12 is transmitted to the input of the computing unit 4. The computing unit 4 forms on the screen of the video monitor 7 a coded image of the information label A. In addition, the computing unit 4 for reproducing the encoded image of the information label A inside the product B for each information pixel generates and transmits control signals to the laser 1 to create laser radiation of the required power, at Anism of changing the focal length of a laser beam focusing lens 3 to change the depth of concentration of the radiant energy of the laser beam and to the displacement drive 9 of the mirror 8 to transfer the concentration point of the radiant energy of the laser beam within the length and width of the encoded image of the information mark A. Laser beam 1 passing through the lens focusing the laser beam 2 and through the reflective surface of the mirror 8, focuses at a certain point in the volume of the optically transparent material of the product B, creating an image of information ion pixel encoded image information label A. In the process of scanning the entire video frame encoded image information mark A is formed completely within the volume of an optically transparent material product B.

Label A can be made directly in the product B itself or pre-made and then “implanted” into product B without the possibility of dismantling. In the first case, the product B should be completely made of optically transparent material. In the second case, product B can be made of optically opaque material, and the material of label A itself must be optically transparent.

To identify the product, an identifier is used in which the encoded image of the information label A, passing through the lens of the identifier 13, focuses on the input of the optical radiation receiver of the identifier 14. From the output of the optical radiation detector of the identifier 14, the encoded image of the information label A is electronically transmitted to the input of the electronic decoder 15 . In the electronic decoder 15, the encoded image of the information label A is decoded and transmitted in decoded form to the input microdisplay 16, on the screen of which a real image of information mark A is formed. From the screen of microdisplay 16 with the help of an eyepiece 17, the real image of information mark A gets into the eye of the observer.

The method of protecting products from counterfeiting when using the optical version of the device can be carried out as follows.

The image of the information label A, which can be a graphic image of the code, is created using the image forming lens of the information label 10, from the output of which it is transmitted to the input of the optical encoder 18.

Since the optical encoder 18 is made in the form of a fiber optic fiber with the location of the optical fibers 21 at the input that is not identical to their location at the output, an optically encoded image of the information label A is created at the output of the optical encoder 18, which through the lens transfers the encoded image of the information label 19 transmitted to the optical input of the optical radiation receiver 11. In the optical radiation receiver 11, which is based on a CCD matrix, the optical form of the image information ki A is converted into electronic form, which is transmitted as a signal to the input of computing unit 4. Computing unit 4 generates an encoded image of information label A on the screen of video monitor 7. In addition, computing unit 4 for reproducing the encoded image of information label A inside product B of each information pixel generates and transmits control signals to laser 1 to create laser radiation of the required power, to the mechanism for changing the focal length of focusing beam of the laser beam 3 to change the depth of concentration of the radiant energy of the laser beam and to the displacement drive 9 of the mirror 8 to transfer the point of concentration of the radiant energy of the laser beam within the length and width of the encoded image of the information mark A. Laser beam 1, passing through the focus lens of the laser beam 2 and reflected from the surface of the mirror 8, focuses at a certain point in the volume of the optically transparent material of the product B, creating an image of the information pixel of the encoded image nformatsionnoy label A. In the process of scanning the entire video frame encoded image information mark A is formed completely within the volume of an optically transparent material product B.

Label A can be made directly in the product B itself or pre-made and then “implanted” into product B without the possibility of dismantling. In the first case, the product B should be completely made of optically transparent material. In the second case, product B can be made of optically opaque material, and the material of label A itself must be optically transparent.

To identify the product, an identifier is used in which the encoded image of the information label A, passing through the lens of the identifier 13, focuses on the input of the optical decoder 20. In the optical decoder 20, the encoded image of the information label is decoded, and in the decoded form through the eyepiece 17, the real image of the information label A gets into the eye of the observer.

The optical encoder 18 and the optical decoder 20 (Fig.3) can be performed as follows. The optical fibers 21 of the length of the optical fiber at the ends are rigidly fixed in relation to each other, for example, using epoxy resin. Then, in the middle part of the length of the optical fiber, the arrangement of the optical fibers 21 is randomly changed with respect to each other. With this changed arrangement with respect to each other, the optical fibers 21 in the middle part are rigidly fixed with an epoxy resin. A piece of fiber in the middle part fixed with epoxy is cut into two parts. One of the parts becomes an optical encoder 18, and the other part an optical decoder 20. Thus, the condition is automatically satisfied that the location of the optical fibers 21 at the inputs of the optical encoder 18 and the optical decoder 20 is not identical to their location fixed at their outputs, but the location of the optical fibers 21 the input of the optical encoder 18 is identical to their location at the output of the optical decoder 20, and the location of the optical fibers 21 at the output of the optical encoder 18 is identical to their location at the input of the optical decoder 20. The optical encoder 18 made by the above method, when changing the direction of the light flux in it, can play the role of the optical decoder 20, and the optical decoder 20 when changing the direction of the light flux in it, can play the role of the optical encoder 18.

In the manufacture of information label A according to well-known technical solutions inside optically transparent materials in the form of an image of a real object or even in the form of an information code, a person copying their images can always correct his copy to full identity, since he knows what is shown even if some either alphanumeric, alphanumeric or bar code.

When you try to copy information label A, made according to the proposed technical solution, this will be much more difficult, since the location inside the frame of the image pixels is randomly changed, the image is a set of visually unrelated small fragments and the copy has no idea what is ideal version of the image to which he should strive.

To identify the product when using the system for receiving, storing, processing and transmitting information about information labels, the output of the optical set-top box 28 is matched to the optical input of the digital camera 27 built into the cell phone 26 and photographing the product information label is performed.

If labels A are made in a material that does not transmit radiation in the visible range, but transmits radiation in the infrared wavelength range (germanium), then a thermal imager is used as an optical prefix 28.

A signal containing information about the received digital photograph is transmitted via cellular communication to a remote system for receiving, storing, processing and transmitting information about information labels.

In the system for receiving, storing, processing and transmitting information about information labels, the signal is received by the transceiver 22 and transmitted to the correlator 23. In the correlator 23, the incoming signal is compared with 25 photographs of various information labels (including the one being checked) stored in the computer memory and a comparison signal is generated , which is transmitted to the comparator 24. If the result is positive, the comparison signal has a maximum amplitude exceeding the value of the reference voltage supplied to the comparator 24. In this case, the comparator 24 automatically generates a response signal arriving at the transceiver 22, indicating the authenticity of the product. The transceiver 22, in turn, generates a signal that is transmitted via cellular communication to the cell phone 26.

Thus, from the foregoing, it follows that the proposed method of protecting products from counterfeiting and a device for its implementation ensure the achievement of a technical result, namely, the maximum difficulty of identical copying of the encoded image of the information mark due to insufficient information necessary for its implementation.

Claims (6)

1. A method of protecting products from counterfeiting, including obtaining an image of an information label inside the volume of an optically transparent material by changing its structure by heat treatment due to the concentration of radiant energy at a certain point in the volume of the material, moving the point of concentration of radiant energy inside the volume of the material and changing the power of radiant energy for this moving according to a given algorithm, characterized in that the real image of the information label is pre-converted to encoded th form and within the optically transparent material image information marks are formed in encoded form with the possibility of decoding in real form for subsequent visual identification. 2. A device for protecting products from counterfeiting, including a laser, a laser beam focusing lens with a mechanism for changing its focal length, a computing unit, a video monitor, a movable mirror, a mirror moving drive, characterized in that the device further includes an information imaging lens tags, an optical radiation receiver, an electronic image label image encoder and an identifier including an identifier lens, an optical radiation receiver the identifier, an electronic decoder, an electronic microdisplay and an eyepiece, wherein the output of the information mark image forming lens is optically connected to the optical input of the optical radiation receiver, the electrical output of which is electrically connected to the input of the information mark image encoder, the output of the information mark image encoder is electrically connected information input of the computing unit, the first, second, third and fourth outputs of the computing unit are connected respectively with the input of the video monitor, the input of the drive for moving the mirror, the input of the mechanism for changing the focal length of the laser focus lens and the control input of the laser, while the optical output of the laser is optically connected to the optical input of the focus of the laser beam, the optical output of the laser focus lens through the reflecting surface the mirror is optically connected to the installation zone of the workpiece; the identifier lens is optically connected to the receiver input optically identifier of radiation, the optical radiation output of the receiver identifier is electrically connected to the electronic decoder input, the output of the electronic decoder is electrically connected to the input of the electronic microdisplay and microdisplay screen optically coupled to the eyepiece. 3. A device for protecting products from counterfeiting, including a laser, a laser beam focusing lens with a mechanism for changing its focal length, a computing unit, a video monitor, a movable mirror, a mirror moving drive, characterized in that the device further includes an information image forming lens tags, optical radiation receiver, optical encoder image information label, lens transfer encoded image information label and identification a torus including an identifier lens, an optical decoder and an eyepiece, wherein the output of the information mark image forming lens is optically connected to the input of the optical information mark image encoder, the output of the information mark optical image encoder is optically connected to the input of the information mark image transfer lens, the output of the information image transfer lens tags, optically connected to the input of the optical radiation receiver, the output of the optical radiation receiver is electrically connected with the input of the computing unit, the first, second, third and fourth outputs of the computing unit are electrically connected respectively to the input of the video monitor, the input of the mirror moving drive, the input of the mechanism for changing the focal length of the focusing lens of the laser beam and the control input of the laser, while the optical output of the laser is optically coupled to optical input of the laser focus lens, the optical output of the laser focus lens through the reflective surface of the mirror is optically connected to the th installation of the workpiece, the identifier lens is optically connected to the input of the optical decoder, the output of the optical decoder is optically connected to the eyepiece. 4. The device for protecting products from counterfeiting according to claim 3, characterized in that the optical encoder and the optical decoder are made in the form of fiber optic optical fibers with a fixed arrangement of optical fibers at their inputs that is not identical to their fixed location at the outputs, while the arrangement of optical fibers the input of the optical encoder is identical to their location at the output of the optical decoder, and the location of the optical fibers at the output of the optical encoder is identical to their location at the input of the optical decoder. 5. A device for protecting products from counterfeiting according to claim 2 or 3, characterized in that it further includes a transceiver, a correlator, a comparator and a computer, a remote system for receiving, storing, processing and transmitting information about information labels, a communication tool with a reception system , storage, processing and transmission of information about information labels, made in the form of a cell phone with an integrated camera, having made in the form of an optical set-top box, a device for reading information about information labels, when the output of the optical set-top box is optically connected to the optical input of the integrated camera, the electrical output of the transceiver is electrically connected to the first input of the correlator, the second input of which is electrically connected to the output of the computer, and the output is electrically connected to the first input of the comparator, the output of the comparator is electrically connected to the electrical input of the transceiver, and the second input of the comparator is electrically connected to the source of the reference voltage. 6. A method of manufacturing an optical encoder and an optical decoder according to claim 4, the implementation of which the optical fibers of the length of the fiber optic fiber at the ends are rigidly fixed to each other with glue, then in the middle region of the length of the fiber optic fiber in relation to each other arbitrarily change and with this changed arrangement in the middle region of the length of the fiber optic fiber, the optical fibers are also rigidly fixed to each other with glue, then a segment of optical fiber fixed middle area of adhesive is cut into two parts.

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