RU2310915C1 - Method for checking authenticity of a document, protected from forgery, and device for realization of said method - Google Patents

Abstract

FIELD: methods for detecting authentic and fake documents with different means of forgery protection.

SUBSTANCE: the method is realized by means of a device for checking authenticity of document, including source of radiation of visible non-polarized light for possible detection of magnetic mark and visualization of its image, on optical axis of which polarizer and magneto-optical sensitive element are mounted, the element made in form of film of bismuth-containing ferrite-garnet, applied to transparent substrate, analyzer, mounted on the way of light stream reflected from magneto-optical sensitive element, source of constant magnetic field for magnetization of controlled zone of sheet material, second source of visible non-polarized light for visualization of visible image of zone being researched, positioned on one side with first light source relatively to plane of sensitive element, image registration block, optically connected to analyzer, and block for controlling lighting modes of the zone being examined.

EFFECT: increased trustworthiness when determining authenticity of a document protected from forgery due to increased number of evaluation signs.

2 cl, 2 dwg

Description

The invention relates to methods for identifying genuine and false documents with various means of protection against fakes. Such documents include banknotes, securities and identification documents, such as passports.

To prevent counterfeiting of banknotes, securities and identification documents, they are provided with various types of protection, one of which is a magnetic tag. The essence of magnetic protection lies in the fact that magnetic marks are applied to the document in the form of a system of strokes or drawings made with a paint containing ferromagnetic particles. At the stage of verification of such documents, it is necessary to identify the presence and location of magnetic marks, and then compare them with the images of the marks on the original document. In the presence of drawings, letters or numbers applied with "magnetic" paint, it is necessary to visualize such prints, allowing you to compare the image of the magnetic mark with the image of the magnetic mark on an original document.

A known method of verifying the authenticity of a document is to scan the paper relative to a magnetic induction head, and the presence and magnitude of the current induced in its coil are used to judge the presence of a magnetic mark of ferromagnetic particles (see US 4797938, WILL TERRY A, 01/10/1989). To implement the known method, a device for verifying the authenticity of banknotes and securities is used, in which the magnetic induction head is a sensitive element for verification.

However, the known method does not provide visualization of the fingerprint of the magnetic mark, and therefore cannot reliably separate genuine documents from counterfeit documents into which magnetic marks made in the form of drawings are embedded in any way.

The closest analogue of the method is a method of verifying the authenticity of a document protected from fakes, which consists in determining the presence of a magnetic mark of the document with subsequent visualization of its image by placing a magneto-optical sensitive element on the surface of the document in the area where the magnetic mark is located, magnetizing the studied area until saturation, irradiation of a magneto-optical sensitive element by a stream of polarized light with subsequent transformation of light modulation along the plane polarization into light modulation in intensity and registration based on changes in the intensity of the image of the magnetic mark, comparing the image with the image of the magnetic mark of an authentic document (see RU 93009536 A1, Physicotechnical Center at the SRCFT, 04/30/1995).

The method is implemented using a device for verifying the authenticity of a document protected from forgery, containing a visible light source, on the optical axis of which there is a polarizer and a magneto-optical sensing element, including a bismuth-containing ferrite garnet film deposited on a transparent substrate, an analyzer mounted on the beam axis light reflected from a magneto-optical sensing element, and a source of a constant magnetic field in the form of a magnetic system including permanent magnets for For the formation of a uniform magnetic field in the control zone with an intensity sufficient to magnetize the studied area of the document and a magnetic induction vector directed at an angle of no more than 5 ° to the surface of the magneto-optical sensitive element (see ibid.). The known device is the closest analogue.

The known method of verifying the authenticity of a document protected from counterfeiting provides the visualization of magnetic marks, which makes it possible to more accurately separate genuine documents from counterfeit ones. However, the known method does not allow verification of the entire surface of the studied area of the controlled document in visible light. As you know, the analysis of the visible image of the document allows you to increase the number of evaluation features, and therefore, to increase the reliability of the authentication of the checked document. In addition, the analysis capabilities of the visible image make it possible to more accurately determine the location on the document of a zone with a magnetic mark, which allows the formation of a more reliable image of the magnetic mark. If the area of the magnetic mark is incorrectly selected, an invalid image of the magnetic mark can be obtained.

Thus, the absence in the known method of checking the image of the document in the visible range makes it less informative, and therefore less reliable.

The objective of the invention is to provide a method for verifying the authenticity of a document protected from fakes, and a device for its implementation, with increased reliability of determining the authenticity of a document.

The technical result consists in increasing the reliability of determining the authenticity of a document protected from fakes by increasing the number of evaluative features. The invention allows verification of the authenticity of the visible image of the document, verification of the relative position of magnetic marks, as well as verification of areas of the document sealed with non-magnetic paint.

This is achieved by the fact that in the method of verifying the authenticity of a document protected from fakes, which consists in the fact that a magneto-optical sensing element made in the form of a film of bismuth-containing ferrite garnet deposited on a transparent substrate is placed on the document’s studied area and the magnetic authenticity is checked marks and a visible image of the studied area, for which the zone is selected both with the presence of the proposed magnetic mark, and with its absence. In order to be able to detect a magnetic mark and visualize its image, the studied area is exposed to a uniform magnetic field with a strength sufficient to magnetize the magnetic mark, then the magneto-optical sensitive element is irradiated with a light flux from a polarized light source and the light reflected from the surfaces of the magnetic sensitive element is analyzed, followed by light modulation conversion along the plane of polarization to the modulation of light in intensity, recorded on the basis of changes l light flux image of the magnetic mark in the study area, which is compared with the image of the magnetic mark in the same area of the original document. To visualize the visible image of the studied area, the magneto-optical sensitive element is irradiated with a light flux from a source of visible unpolarized light located on one side with a polarized light source relative to the magneto-optical sensitive element, and the light flux diffusely reflected from the surface of the document is converted into a visible image of the studied area, which is compared with a visible image of a similar area of the original document. The authenticity of the document is determined by comparing the obtained images of magnetic marks and visible images of all the studied areas with images of similar magnetic marks and similar visible zones of the original document.

The use of a sensitive element, including a film of bismuth-containing ferrite garnet, deposited on a transparent substrate, allows you to further verify the authenticity of the document in the visible range. In this case, when verifying the authenticity of the magnetic mark to reflect polarized light incident on the sensitive element, use is made of the interface between an optically denser medium — a magneto-optical sensitive element and an optically less dense medium — an air gap between the document and the magneto-optical sensitive element, which allows significant reflection from the surface of the document being checked part of the incident light. The absence of a reflective layer on the sensing element makes it possible to verify the visible image of the surface of the entire studied area of the document by illuminating the magneto-optical sensitive element with visible unpolarized light. This makes it possible to compare the image of the study area with the image of a similar area of the original document.

Thus, the proposed method involves an increase in the number of evaluative features, and therefore, allows to increase the reliability of determining the authenticity of a document. In addition, verification of a document not only in areas where there is a magnetic mark, but also in areas where they are missing, also allows you to increase the reliability of determining the authenticity of the document being checked.

In the case of checking documents made using the "Oryol" printing or "iris" printing, in addition to analyzing the visible image of the document under control in the proposed method, it is possible to analyze the continuity of the lines of the printing element when switching from one type of ink to another. It also increases the likelihood of determining the authenticity of the document.

To increase the reliability of determining the authenticity of the document being verified, the studied area is checked in infrared light. To do this, it is irradiated with a stream of non-polarized infrared radiation, the radiation source of which is located on one side with the light sources relative to the magneto-optical sensing element, and the image of the studied area is recorded in diffuse reflected infrared light, the resulting image is compared with the image in diffusely reflected infrared light of a similar zone of a genuine document. The comparison results are used to determine the authenticity of the document.

The method is implemented using a device for verifying the authenticity of a document protected from fakes, containing a radiation source of visible non-polarized light, on the optical axis of which there is a polarizer and a magneto-optical sensing element, including a bismuth-containing ferrite garnet film deposited on a transparent substrate, an analyzer installed in the path a stream of light reflected from a magneto-optical sensitive element, and a source of a constant magnetic field in the form of a magnetic system, including permanent magnets to form a uniform magnetic field with a strength sufficient to magnetize the studied area of the document and a magnetic induction vector angled to the surface of the magneto-optical sensing element into which according to the invention a second source of visible unpolarized light is introduced, an image recording unit optically coupled to the analyzer , and the control unit for the modes of illumination of the studied area, the output connected to the power inputs of the light sources, and the input to the bl cu of the supply voltage, while the light sources are located on one side relative to the plane of the sensor, the magnetic induction vector of the magnetic field formed by the magnets is directed at an angle of no more than 15 ° to the surface of the magneto-optical sensor, and the second light source is installed at an angle to the plane of the sensor, providing the possibility of highlighting the studied area so that when reflected from the surfaces of the sensing element and the surface of the document, the advantage but a diffuse light beam reflected from the document surface, got through the analyzer to the image recording unit.

The device may also include a collimator located on the optical axis of the first light source in front of the polarizer.

In one embodiment, the device further includes a non-polarized infrared source located on one side with the light sources relative to the plane of the sensor, and the control unit is further provided with elements for connecting the infrared source to the power supply unit, the radiation source being installed at an angle to the plane of the sensor providing the ability to illuminate the magneto-optical sensing element so that when reflected from the surfaces of the sensing element and the surface of the document, the predominantly diffuse infrared radiation stream reflected from the surface of the document passed through the analyzer into the image registration unit.

In the particular case of permanent magnets can be equipped with magnetic cores, ensuring the uniformity of the magnetic field in the studied area, its predetermined orientation and the required magnitude of tension.

In the particular case, the registration unit can be made in the form of a photodetector, for example, in the form of a photodetector array.

The registration unit can be made in the form of an observing optical system, which can be installed before or after the analyzer. In addition, the analyzer can be installed in the observation optical system itself.

The registration unit may be made in the form of a video camera connected to a video signal display unit, for example, a monitor.

In the particular case, the display unit can be made in the form of a computer with a video capture module for the possibility of computer processing of valuation features and making decisions.

To reduce the gap between the magneto-optical sensitive element and the document to be controlled, the device can be equipped with a node for pressing the sensitive element to the surface of the document being checked.

For ease of operation, the magneto-optical sensing element is removable and installed with the possibility of replacement.

The invention is illustrated by drawings. Figure 1 shows a diagram of one of the variants of the proposed device, figure 2 is a diagram of another variant of the device.

The device for checking the authenticity of a document protected from fakes, shown in figure 1, contains two sources 1 and 2 of visible unpolarized light, a polarizer 3, a magneto-optical sensing element 4, an analyzer 5 and a recording unit 6, a magnetic system of two permanent magnets 7 and a block 8 control the backlight modes connected to the block 9 of the supply voltage.

Light sources 1 and 2 are located one side from the surface of the magneto-optical sensing element 4.

The magneto-optical sensing element 4 includes a domain-containing bismuth-containing ferrite garnet film 10 deposited on a transparent substrate 11.

The method using the proposed specific implementation of the device is as follows.

The magneto-optical sensing element 4 is located on the surface of the document, for example banknotes 12, so that the area with the alleged magnetic mark is in contact with its working surface 10.

Using the backlight control unit 8, a source of visible unpolarized light 2 is connected to a supply voltage source 9. The light from the source 2 passes through the magneto-optical sensor 4 to the surface of the banknote 12. Moreover, the light source 2 is mounted to the plane of the sensor 4 at an angle, which makes it possible to illuminate the studied area so that its light flux during diffuse scattering from the surfaces of the sensor 10, 11 and banknotes 12 got through the analyzer 5 into the image recording unit 6, and the directionally-reflected from the surfaces of the magneto-optical sensitive element mainly did not get l.

In block 6 registration form on the basis of the analyzer data a visible image of the studied area of the checked banknote. Compare the resulting image with the image of a similar area of a genuine banknote. The comparison results are used in determining the authenticity of the banknote. In addition, according to the results of the comparison, it is possible to clarify the location of the zone of the proposed magnetic mark and change the position of the magneto-optical sensing element 4 if necessary.

Then, using block 8, the light source 2 is disconnected from the source 9 and the light source 1 is connected to it. The light from the source 1 falls on the polarizer 3, after which it becomes linearly polarized. A stream of linearly polarized light is directed to a magneto-optical sensitive element 4.

The magnetic system of permanent magnets 7 forms a uniform magnetic field with a strength sufficient to magnetize the magnetic mark. In this case, the magnets 7 are arranged so that the magnetic induction vector is oriented at an angle of no more than 15 ° to the plane of the magneto-optical sensing element 4.

Obviously, when the magnetic induction vector is oriented at an angle to the plane of the sensing element 4, a spurious image appears, which has the greater contrast, the larger the angle. However, to ensure a larger area of the document’s controlled area corresponding to the area of the sensitive element, it is necessary to ensure uniformity of the magnetic field over its entire area, which is technically difficult and not always feasible. It was experimentally established that when the magnitude of the magnetic induction vector to the plane of the sensing element is not more than 15 °, the parasitic image, as a rule, does not interfere with the recognition of the magnetic mark.

A magnetic field in the direction perpendicular to the plane of the magneto-optical element 4 acts on the film 10 and reconstructs the labyrinth domain structure in it in accordance with the structure of the magnetic label.

Polarized light passing through the film 10, due to the Faraday effect, rotates the plane of polarization, depending on which domain of the ferrite garnet of the domain-containing film 10 passes through the light. After reflection from the surface of the film 10, the light again passes through the domain-containing film 10 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 domain-containing film 10 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 surface of the film 10 passes through an analyzer 5, which converts the modulation of light along the plane of polarization into the modulation of light by intensity, which is then recorded in the recording unit 6 as an image of a magnetic mark.

It should be noted that polarized light reflected from the first surface of the substrate 11 along the beam also enters the analyzer 5 and is able to reduce the contrast of the image of the magnetic mark due to spurious illumination that does not carry information about the magnetization of the investigated zone of the banknote 12.

To compensate for the effects of spurious illumination in the device, the analyzer 5 is oriented in such a way as to ensure maximum image contrast due to the absorption of the polarized light by the analyzer 5 of the initial polarization.

In addition, a part of the polarized light, after passing through the magneto-optical sensing element 4, reaches the surface of the banknote 12. When it is diffusely reflected from the surface 12 of the banknote, part of the diffusely reflected light can enter the recording unit 6.

However, this does not lead to a significant deterioration in the image quality of the magnetic mark, since with diffuse reflection, polarized light turns into non-polarized, and approximately 50% of its power, which reaches the analyzer 5, is absorbed by it and does not reach the recording unit 6. In addition, the energy of diffuse light is dissipated in a wide solid angle. In this connection, only a part of it reaches the analyzer 5 and can go to the registration unit 6.

The amount of this energy can be reduced by increasing the distance from the banknote to the registration unit 6 and equipping the light source 1 with a collimator 13. In this case, the amount of useful light flux will not weaken with increasing distance from the banknote to the registration unit 6, since it propagates in the form of slightly divergent beam.

The resulting image of the magnetic tag is compared with the image of the magnetic tag of a genuine banknote. Based on the results of this comparison, they conclude that the magnetic mark is authentic.

Then, in a similar manner, they verify the authenticity of the banknote zones in which there is no magnetic mark.

Moreover, to achieve the specified technical result, it does not matter when it is necessary to check the authenticity of the magnetic mark and the visible image. In the proposed method, you can first verify the authenticity of the visible image of the studied area, and then check the authenticity of the magnetic mark and vice versa.

In any case, the authenticity of the verified banknote is determined by the results of the verification of the authenticity of all the studied areas.

In the presented specific example of the device, the magnetic system includes at least two permanent magnets 7 made of an alloy based on, for example, samarium-cobalt. Permanent magnets 7 are mounted in such a way that they form a uniform magnetic field. Magnets 7 may be provided with magnetic cores (not shown in the drawing).

As the polarizer 3 and the analyzer 5 can be used film polaroids. The transparent substrate 11 of the sensing element 4 is made of gadolinium-gallium garnet, the domain-containing film 10 is made of bismuth-containing ferrite garnet.

The device may also include a source 14 of non-polarized infrared radiation (see figure 2), installed on one side with light sources to the plane of the sensing element 4. Moreover, the radiation source is installed at an angle that allows the illumination of the studied area so that when reflected from the surface of the sensitive element and the document, the predominantly diffuse light flux passed through the analyzer into the image registration unit, but the directed one did not.

With this embodiment of the device, the control unit 8 is further provided with elements for connecting the infrared radiation source 14 to the supply voltage unit 10.

When using such an embodiment of the device, an additional evaluation feature is used - the image of the banknote in infrared light. The device in this case works as follows.

After comparing the image of the magnetic mark and the visible image of the test area with a similar area of the genuine banknote, sources 1 and 2 are turned off and turn on the source 14 of non-polarized infrared radiation. They irradiate the studied area of the banknote surface. In this case, only the diffuse light flux enters through the analyzer 5 into the image recording unit 6, and the directionally scattered light does not enter.

In this case, the registration unit 6 registers the image of the studied area in infrared light. The resulting image is compared with an infrared image of a similar area of a genuine banknote.

The authenticity of the banknote is determined by comparing the images of the magnetic mark, as well as the images of all the studied areas in both infrared and visible light.

As the tests showed, the proposed method and device for its implementation allows with a sufficient degree of reliability to verify the authenticity of documents with various means of protection against counterfeiting.

Claims (25)

1. A method of verifying the authenticity of a document protected from fakes, which consists in the fact that a magneto-optical sensing element made in the form of a film of bismuth-containing ferrite garnet deposited on a transparent substrate is placed on the studied area of the document, and the authenticity of the magnetic mark and the visible image is checked the studied zone, for which the zone is selected both with the presence of the proposed magnetic mark and with its absence, while for the possibility of detecting the magnetic mark and visualizing it and images on the studied area are exposed to a uniform magnetic field, the magneto-optical sensor is irradiated with a light stream from a source of polarized light and the light reflected from the surfaces of the magneto-optical sensor is analyzed, followed by the conversion of light modulation along the plane of polarization into light modulation in intensity, and the image is recorded based on changes in the light flux intensity magnetic labels in the study area, which is compared with the image of the magnetic m For the visualization of the visible image of the studied area, the grids in the same area of the original document are irradiated with a light flux from a source of visible unpolarized light located on one side with a polarized light source relative to the magneto-optical sensitive element, and the light flux diffusely reflected from the document surface is converted into the visible image of the study area, which is compared with the visible image of the same area of the original document, moreover, the authenticity of the document is determined by comparing the obtained images of magnetic marks and visible images of all the studied areas with images of similar magnetic marks and similar visible images of the original document. 2. The method according to claim 1, characterized in that for checking the test area in infrared light, it is irradiated with a stream of non-polarized infrared radiation, the radiation source of which is located on one side with light sources relative to the magneto-optical sensitive element, and the image of the test area is recorded in diffuse reflected infrared light, the resulting image is compared with the image in diffusely reflected infrared light of the same area of the original document, the comparison results use and determining the authenticity of the document. 3. Device for verifying the authenticity of a document protected from fakes, containing a radiation source of visible non-polarized light, on the optical axis of which there is a polarizer and a magneto-optical sensing element, including a film of bismuth-containing ferrite garnet, deposited on a transparent substrate, an analyzer installed in the path of light flux reflected from a magneto-optical sensor and a source of a constant magnetic field in the form of a magnetic system including permanent magnets for shapes homogeneous magnetic field in the control zone with an intensity sufficient to magnetize the controlled zone of the sheet material and a magnetic induction vector angled to the surface of the magneto-optical sensing element, characterized in that a second source of visible unpolarized light is introduced into it, located on one side of the first light source relative to the plane of the sensing element, an image recording unit optically coupled to the analyzer, and a mode control unit the illumination of the studied area, the output connected to the supply inputs of the light sources, and the input to the power supply unit, while the second light source is installed at an angle to the plane of the sensitive element, which allows the illumination of the studied area so that when reflected from the surfaces of the sensitive element and of the surface of the document, a predominantly diffuse light flux reflected from the surface of the document fell through the analyzer into the image registration unit, and the magnetic induction vector magnetic field generated by magnets is directed at an angle not exceeding 15 ° to the surface of the magneto-sensitive element. 4. The device according to claim 3, characterized in that an infrared non-polarized radiation source is introduced into it, located on one side with the light sources relative to the plane of the sensing element, and the control unit is further provided with elements for connecting the infrared radiation source to the supply voltage unit, wherein the source radiation is mounted to the plane of the sensitive element at an angle that allows the magneto-optical sensitive element to be illuminated so that when reflected uu infrared radiation from the surfaces of the sensor and the surface of a document mainly diffuse flux of radiation reflected from the document surface, got through the analyzer to the image recording unit. 5. The device according to claim 3 or 4, characterized in that a collimator is inserted into it, placed on the optical axis of the first light source in front of the polarizer. 6. The device according to claim 5, characterized in that the registration unit is made in the form of a photodetector. 7. The device according to claim 6, characterized in that the photodetector is used as a photodetector. 8. The device according to one of paragraphs.3, 4, 6 or 7, characterized in that the permanent magnets are equipped with magnetic circuits, ensuring uniformity of the magnetic field, its predetermined orientation and magnitude of the intensity. 9. The device according to claim 5, characterized in that the permanent magnets are equipped with magnetic circuits, ensuring the uniformity of the magnetic field, its predetermined orientation and magnitude of tension. 10. The device alone according to claims 3, 4, 6, 7 or 9, characterized in that the registration unit is made in the form of an observing optical system. 11. The device according to claim 5, characterized in that the registration unit is made in the form of an observing optical system. 12. The device according to claim 8, characterized in that the registration unit is made in the form of an observing optical system. 13. The device according to claim 10, characterized in that the observing optical system is installed before or after the analyzer. 14. The device according to claim 11 or 12, characterized in that the observation optical system is installed before or after the analyzer. 15. The device according to claim 10, characterized in that the analyzer is installed in an observing optical system. 16. The device according to claim 11 or 12, characterized in that the observation optical system is installed in the observation system. 17. The device according to one of claims 3, 4, 6, 7 or 9, characterized in that the registration unit is made in the form of a video camera connected to a video signal display unit, and the analyzer is included in the optical system of the video camera. 18. The device according to claim 5, characterized in that the registration unit is made in the form of a video camera connected to a video signal display unit, while the analyzer is included in the optical system of the video camera. 19. The device according to claim 8, characterized in that the registration unit is made in the form of a video camera connected to a video signal display unit, while the analyzer is included in the optical system of the video camera. 20. The device according to 17, characterized in that the display unit of the video signals is made in the form of a monitor. 21. The device according to claim 19 or 20, characterized in that the video signal display unit is made in the form of a monitor. 22. The device according to 17, characterized in that the display unit is made in the form of a computer with a video capture module. 23. The device according to claim 19 or 20, characterized in that the display unit is made in the form of a computer with a video capture module. 24. The device according to claim 3, characterized in that it introduced a node clamping the sensing element to the surface of the controlled product. 25. The device according to claim 3, characterized in that the magneto-optical sensing element is installed with the possibility of replacement.

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