RU68731U1 - DEVICE FOR MONITORING THE AUTHENTICITY OF THE DOCUMENT PROTECTED FROM FALSE - Google Patents

Abstract

Device for checking the authenticity of banknotes, securities, passports and other documents protected from fakes. The device contains a visible light source, on the optical axis of which a polarizer and a magneto-optical converter are installed, installed on the path of the light reflected from the converter, an analyzer and a recording unit, as well as permanent magnets for magnetizing the document being monitored. The converter includes a transparent substrate on which a magneto-optical film, a reflective layer and a protective layer are successively applied, thereby increasing the reliability of the device and the quality of the generated magnetic mark images. In this case, the light source, polarizer, analyzer and constant magnetic field source are structurally combined by a housing consisting of two parts - the cover and the base. The registration unit is structurally integrated directly with the lid. This combination of elements allows you to get a compact and easy-to-use device. The base includes a holder with a hole on which is fixedly mounted, partially blocking the hole, the Converter. Such a placement of the transducer allows the device to form simultaneously with the image of the magnetic mark and the visible image of the studied area, which increases the reliability of the document's control for authenticity. The holder is removable, which increases the convenience of operation, since if the converter is damaged, it is enough to replace the holder with a damaged converter with a similar holder with a working converter. 17 s.p. f-ly.

Description

The utility model relates to devices for detecting genuine and false documents protected from fakes.

Such documents include banknotes, securities and identification documents, such as passports.

To prevent forgery of documents, they are provided with some types of protection, one of which is magnetic. The essence of magnetic protection lies in the fact that magnetic marks are applied to the paper in the form of a system of strokes or drawings made with a paint containing ferromagnetic particles. At the stage of verification of such papers, it is necessary to identify the presence and location of magnetic marks, and then compare them with the reference ones. In the presence of drawings, letters or numbers applied with "magnetic" paint, the visualization of such prints is necessary.

A device for controlling the authenticity of documents protected from counterfeit is known, in which the magnetic induction head is a sensitive element for checking the magnetic mark (see US 4797938, WILL TERRY A, 01/10/1989). When scanning paper relative to the induction head by the presence and magnitude of the current induced in its coil, the presence of a magnetic mark is judged. However, such a device does not provide visualization of the fingerprint of the magnetic mark, and, therefore, cannot reliably separate genuine documents from counterfeit ones into which magnetic marks are embedded in any way, even in an arbitrary order, without forming patterns.

A device is known for checking the authenticity of documents protected from fakes (see RU 93009536 A1, Physicotechnical Center at the SRCFT, 04/30/1995), containing a visible radiation source

light, on the optical axis of which a polarizer and a magneto-optical sensing element are installed, including a transparent substrate on which a domain-containing film and a reflective layer are applied sequentially, as well as an analyzer installed in the path of light reflected from the magneto-optical sensitive element, and a constant magnetic field source.

The known device provides the visualization of magnetic marks, which allows more accurately determine the authenticity of the document. However, the service life of the known device is small. This is because when visualizing magnetic marks, the reflective layer of the magneto-optical sensing element is in direct contact with the surface of the document, for example, a banknote. In the known device, the reflective layer of the magneto-optical sensor is made of aluminum. As you know, aluminum is a soft metal. From frequent use, the reflective layer is almost completely erased, while the brightness and contrast of the image of the magnetic mark are deteriorated, and, therefore, the probability of determining the authenticity of the document is reduced.

The closest analogue is a device for checking the authenticity of documents protected from counterfeit, containing a source of visible light radiation, on the optical axis of which there is a diffuser, a polarizer and a magneto-optical sensing element, made in the form of a magneto-optical transducer comprising a transparent substrate on which a magneto-optical film is applied sequentially, a reflective layer and a protective layer, as well as an analyzer installed in the path of light reflected from the magneto-optical sensor element, a constant magnetic field source and a recording unit optically coupled to the analyzer (RU 55177 U1, Sistema LLC, July 27, 2006).

The implementation of the sensitive element with a protective layer allows you to increase the service life of the most sensitive element without reducing the level of its sensitivity, and, consequently, the service life of the device itself.

However, the known device does not provide for the possibility of checking the surface of the studied area of the controlled document in visible light. As you know, a visible image of a document is one of the evaluation features in determining the authenticity of a document. In addition, the visible image of the studied area with greater accuracy allows you to determine the location on the document of the zone with a magnetic mark, which allows you to create a more reliable image of the magnetic mark. If the zone is incorrectly selected, an invalid image of the magnetic mark can be obtained.

The objective of the proposed utility model is to create a device for checking the authenticity of a document protected from fakes, simple and easy to use, with sufficient reliability to separate genuine documents from fake ones.

The technical result consists in increasing the reliability of determining the authenticity of a document by increasing the number of evaluative features, namely, the additional formation of a visible image of the studied area, as well as improving the ease of use through the use of a removable holder on which the magneto-optical sensing element is fixedly mounted.

This is achieved by the fact that in a device for checking the authenticity of a document protected from fakes, containing a source of visible light radiation, on the optical axis of which there is a polarizer and a magneto-optical sensing element, made in the form of a magneto-optical transducer comprising a transparent substrate, onto which a magneto-optical is applied sequentially

a film, a reflective layer and a protective layer, as well as an analyzer installed in the path of light reflected from a magneto-optical sensing element, a magnetic field source, and a recording unit optically coupled to the analyzer, according to a utility model, a radiation source, a polarizer and a constant magnetic field source united by a housing consisting of two parts - the cover and the base, including a removable holder with a hole on which is fixedly mounted, partially blocking the hole, magneto-optical a sensitive element, and the registration unit is structurally integrated with the cover.

A constructive combination of a radiation source, a polarizer, an analyzer, a source of a constant magnetic field and a diffuser in a single case, consisting of two parts - a base and a cover, as well as a constructive combination of a recording unit directly with the cover of the case allow to obtain a compact and convenient device in operation. The use of a base, including a holder on which is fixedly mounted, partially blocking the hole, a magneto-optical sensing element, allows to obtain simultaneously with the image of the magnetic mark and a visible image of the studied area.

In addition, the implementation of the holder removable increases the ease of use, since if the magneto-optical sensor is damaged, it is sufficient to replace the holder with a damaged magneto-optical sensor with a similar holder with a working magneto-optical sensor.

The device may include a diffuser mounted between the light source and the polarizer. The introduction of the diffuser allows you to form a zone with a uniform illumination characteristic sufficient to study the magnetic mark of the document being monitored.

The device may include a capacitor mounted between the light source and the polarizer. The capacitor allows you to create the most effective illumination of the studied area of the document under control.

The base of the housing can be made with the possibility of movement relative to the cover to ensure the closure of the contacts in the power supply circuit of the light source. It is enough to lightly press the housing cover to connect the light source to the power source, which increases the usability of the device.

A constant magnetic field source includes at least two permanent magnets.

In the particular case of permanent magnets can be equipped with magnetic cores, ensuring the uniformity of the magnetic field in the control zone. This improves the contrast and image quality of the magnetic mark.

In one embodiment of the device, the registration unit may include a photo detector. Moreover, the photodetector can be made in the form of a photodetector array

To increase the resulting image, the device may additionally include a lens mounted in front of or after the analyzer.

The device may include a set of lenses. In this case, the analyzer can be installed in front of, before or between the lenses.

The registration unit may include an eyepiece for visually recording images of a controlled document with the eye of an operator.

The registration unit may include a video camera connected to a video display unit, for example, a monitor.

In a particular case, the registration unit may have an additional output for connecting to a computer configured to

display images of the controlled document on the monitor screen.

The computer may be equipped with a program that provides an analysis of the authenticity of the controlled document.

Moreover, in each embodiment of the device, a magneto-optical converter is possible, in which the substrate is made strong, the magneto-optical film is made of bismuth-containing ferrite garnet, the reflective layer is made of aluminum, and the protective layer is made of titanium nitride.

An analysis of the prior art showed that a device is known for checking the product for authenticity, containing a visible light radiation source, on the optical axis of which there is a polarizer and a magneto-optical sensing element in the form of a magneto-optical film, as well as an analyzer installed in the path of light reflected from the magneto-optical sensitive element, a magnetic field source, and a recording unit, optically coupled to the analyzer, structural elements are combined by a housing, the base of which is made in the form a holder with an opening on which the magneto-optical sensing element is fixedly fixed, partially overlapping the opening (see RU 2004126218 A, 02.27.2006). The known device, like the proposed utility model, allows simultaneous control of the visible image of the document surface and the image of the magnetic mark.

However, the known device does not provide adequate reliability due to the use of a magneto-optical sensitive element in the form of a magneto-optical film. As is known, a magneto-optical film has a small thickness and a crystalline structure. Since in the known device the magneto-optical film is placed directly on the surface of the holder, partially blocking the hole, when using the device there is a high

the probability of damage to the magneto-optical sensing element, namely, cracking of the film under pressure as a result of its pressing against the controlled document.

In the proposed utility model, a magneto-optical transducer is used as a magneto-optical sensing element, comprising a transparent substrate on which a magneto-optical film, a reflective layer and a protective layer are sequentially applied. This embodiment of the magneto-optical sensor has several advantages compared with the magneto-optical sensor in the form of a magneto-optical film. The use of a transparent substrate allows the protection of the magneto-optical film. The use of a reflective layer allows to improve the image quality of the magnetic mark, and the use of a protective layer allows to protect the reflective layer. Thus, the magneto-optical sensitive elements in the proposed utility model and the known device cannot be considered equivalent.

In addition, the implementation of the holder removable allows you to improve the operational characteristics of the device, because when the magneto-optical sensor fails, it is quite simple to replace the holder with a damaged magneto-optical sensor with a holder with a working magneto-optical sensor.

Thus, the utility model meets the condition of patentability “novelty”.

The utility model is illustrated by drawings.

In Fig 1 presents a schematic diagram of one of the possible embodiments of the proposed device.

Figure 2 shows one of the possible embodiments of the base of the device casing with a holder on which a magneto-optical transducer is mounted.

A device for checking the authenticity of a document protected from fakes contains a housing consisting of a base 1 and a cover 2. At the base 1, a window is made in which a removable holder 3 with an opening 4 is installed. The holder 3 is made with grooves in which, partially overlapping the opening 4 , the magneto-optical transducer 5 is fixedly fixed.

The visible light radiation source 6, the diffuser 7, the polarizer 8, the analyzer 9, and the permanent magnets 10 are structurally integrated by the housing, and the registration unit 11 is structurally integrated directly with the housing cover 2.

The magneto-optical transducer 5 includes a transparent substrate 12, on which a magneto-optical film 13, a reflection layer 14 and a protective layer 15 are sequentially applied. Moreover, the transducer 5 is mounted on the holder 3 by gluing a transparent substrate 12 thereto. The substrate 12 is made strong, the film 13 is made of bismuth-containing ferrite garnet, the reflective layer 14 is made of aluminum, and the protective layer 15 is made of titanium nitride. The strength of the substrate 12 is provided through the use of durable material or by increasing its thickness.

The device also includes an autonomous power source 16 located in the housing.

The device operates as follows.

The base 1 of the housing is moved along the surface of the document to be monitored until the portion of the pattern that needs to be checked for the presence of magnetic paint is combined with the surface of the magneto-optical transducer 5.

The presence of the holder 3 with the hole 4 allows during operation of the device to see part of the pattern on the surface of the document being monitored, limited by the area of the hole 4, and in addition, a magneto-optical converter 5 superimposed on this part of the pattern.

When the device is operating, the power source 16 is connected to the light source 6. The light from the source 6 is scattered by the diffuser 7 and sent to the polarizer 8. After passing through the polarizer 8, the light becomes plane-polarized and enters the magneto-optical film 13 of the magneto-optical transducer 5, pressed against the surface of the controlled document. Its scattering field acts on the magneto-optical film 13 and reconstructs the domain structure in it in accordance with the structure of the magnetic label. Therefore, polarized light passing through the magneto-optical film 13, due to the Faraday effect, rotates the plane of polarization, depending on which domain of the ferrite garnet passes light. After reflection from the reflecting layer 14, the light again passes through the magneto-optical film 13 and the plane of its polarization is again rotated by the same angle and in the same direction as during the first passage. Thus, the double passage of light through a magneto-optical film 13 doubles the angle of rotation of the plane of polarization of light, thereby increasing the sensitivity to the magnetic field. The light reflected from the reflecting layer 14 passes through an analyzer 9, which converts the modulation of light along the plane of polarization into the modulation of light by intensity, which is then recorded in the registration unit 11.

The most high-quality visualized image of the magnetic mark is achieved when the intensity of the magnetic fields of scattering from the sections of the magnetic pattern is maximum.

Under normal conditions, the magnetic fields of dispersion of magnetic patterns on documents, such as banknotes, are negligible

due to the magnetic softness of magnetic inks, they do not significantly affect the configuration of the domain structure of the magneto-optical transducer 5. Their magnetic images will be low-contrast and unsharp. To increase the contrast and image quality of a document’s magnetic label, for example, a banknote, it is magnetized using a constant magnetic field source including permanent magnets 10 until it is saturated so that the domain structure in the film 13 changes as little as possible under the action of the magnetizing field.

In the presented specific example of the device, the magnetic system includes at least two permanent magnets 10 made of an alloy based on, for example, samarium-cobalt. Permanent magnets 10 are installed in such a way that they form a uniform magnetic field in the control zone, sufficient to magnetize the magnetic label and not significantly affect the configuration of the domain structure of most of the magneto-optical film 13. Moreover, the magnetic field strength should be sufficient to magnetize the ferromagnetic material of the magnetic label to areas of significant nonlinearity of the hysteresis loop, or until it is completely saturated.

In order that the magnetizing field does not have a significant effect on at least part of the magneto-optical transducer 5, the permanent magnets 10 are placed so that the magnetic induction vector is directed at an angle that is minimally possible with respect to the plane of the magneto-optical transducer 5. As a rule, this the angle is not more than 5 °.

Magnets 10 may be provided with magnetic cores (not shown). This allows for the greatest uniformity of the magnetic field in the area of the magneto-optical transducer 5 and the minimum angle of the magnetic induction vector along

relation to it, and, consequently, the image quality of the magnetic mark.

At the same time, polarized light enters through the hole 4, not blocked by the transducer 5, on the surface of the document under study and diffusely diffuses from it. A part of the light diffusely scattered from the surface of the document under examination passes through the analyzer 9 with a partial attenuation and is recorded in block 11. Since the thickness of the magneto-optical transducer 5 is not large, in the recording device 11, the image of the studied area of the document under control is constructed as sharply as the image of the magnetic mark.

The ability to analyze a visible image allows you to increase the number of evaluative features while authenticating a document protected from fakes. In addition, this allows you to more accurately determine the location of the magnetic marks due to the ability to combine part of the pattern printed with magnetic ink, with a magneto-optical element 5.

The device is industrially applicable. The elements used in it are known and widely used in the art.

As the tests showed, the proposed device allows with a sufficient degree of reliability to determine the authenticity of the controlled document.

Claims (18)

1. A device for checking the authenticity of a document protected from fakes, containing a source of visible light radiation, on the optical axis of which a polarizer and a magneto-optical sensing element are installed, made in the form of a magneto-optical transducer comprising a transparent substrate on which a magneto-optical film, a reflective layer and a protective layer are sequentially applied a layer, as well as an analyzer installed in the path of light reflected from a magneto-optical sensitive element, a source of constant mag a magnetic field, and a recording unit optically coupled to the analyzer, characterized in that the radiation source, polarizer and magnetic field source are structurally combined in a housing made of two parts - a cover and a base including a removable holder with an opening, while the holder is fixedly mounted, partially overlapping the hole, a magneto-optical sensing element, and the registration unit is structurally integrated with the cover. 2. The device according to claim 1, characterized in that a diffuser is installed between the light source and the polarizer. 3. The device according to claim 1, characterized in that a capacitor is installed between the light source and the polarizer. 4. The device according to any one of claims 1, 2 or 3, characterized in that the base of the housing is movable with respect to the lid to provide contact closure in the power supply circuit of the light source. 5. The device according to any one of claims 1, 2 or 3, characterized in that the source of the constant magnetic field includes at least two permanent magnets. 6. The device according to claim 5, characterized in that the permanent magnets are equipped with magnetic circuits that ensure the uniformity of the magnetic field in the control zone, its predetermined orientation and magnitude of tension. 7. The device according to any one of claims 1, 2 or 3, characterized in that the registration unit includes a photodetector. 8. The device according to claim 7, characterized in that the photodetector is used as a photodetector. 9. The device according to any one of claims 1, 2 or 3, characterized in that a lens is installed in it, installed before or after the analyzer. 10. The device according to any one of claims 1, 2 or 3, characterized in that a set of lenses is introduced into it, while the analyzer is installed in front of, before or between the lenses. 11. The device according to any one of claims 1, 2 or 3, characterized in that the registration unit includes an eyepiece for visual registration of images of a controlled document with the eye of the operator. 12. The device according to claim 9, characterized in that the registration unit includes an eyepiece for visual recording of images of a controlled document by the eye of the operator. 13. The device according to claim 10, characterized in that the registration unit includes an eyepiece for visual recording of images of a controlled document by the eye of the operator. 14. The device according to any one of claims 1, 2 or 3, characterized in that the registration unit includes a video camera with a video signal display unit. 15. The device according to 14, characterized in that the display unit of the video signals is made in the form of a monitor. 16. The device according to any one of claims 1, 2 or 3, characterized in that the registration unit has an additional output for connecting to a computer configured to display images of a controlled document on a monitor screen. 17. The device according to clause 16, wherein the computer is equipped with a program that provides an analysis of the authenticity of the controlled document. 18. The device according to any one of claims 1, 2 or 3, characterized in that the transparent substrate of the magneto-optical transducer is made strong, the magneto-optical film is made of bismuth-containing ferrite garnet, the reflective layer is made of aluminum, the protective layer is made of titanium nitride.