RU2505863C2 - Apparatus for detecting security features when authenticating security papers and documents - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: electromagnetic radiation generator is made in form of a linear array consisting of similar light-emitting diodes 19, having a length which is not shorter than the width of the detected area. A linear photodetector array also consists of similar photodiodes 20, each placed opposite the light-emitting diodes. Adjacent photodiodes 20 of the photodetector are switched in pairs with the possibility of detecting the analysed object simultaneously on all formed channels. Values of given characteristic parameters of the generated luminescence radiation, which corresponds to areas of the surface, i.e., response detected by the photodetector, are the damping characteristic of the generated luminescence radiation and the topology of arrangement of security marks.

EFFECT: high accuracy of authenticating and identifying security papers and documents, compact and simple device.

4 cl, 16 dwg

Description

The invention relates to optical instrumentation, in particular, to hardware optoelectronic devices for non-destructive verification of the authenticity of the studied objects, and can be used mainly in banking equipment and forensics to verify the authenticity of banknotes, securities and other equipped with machine-readable security features (in particular spectral luminescent) original documents.

The present technical solution can be applied in particular to banknote processing machines, for example, to counting and sorting machines (CCM) and / or banknote counting machines, and / or cash machines.

Until now, restrictions on the overall dimensions of devices used to verify the objects under study, for example, such as banknotes or other securities and documents, continue to apply. First of all, for devices that should be distinguished by their universality of use, for example, at cash registers or in cash registers. In addition, it is also necessary to comply with the requirement to ensure reliable verification of the maximum possible number of physical properties by the same device, as a result of which the overall parameters of such devices increase accordingly.

Various kinds of original objects (primarily banknotes, documents protected against counterfeiting, identification cards or securities, excise stamps, etc.) are sealed with protective printing inks suitable for this purpose in certain areas of their surface to increase their degree of protection against counterfeiting. which in the visible region of the spectrum (i.e., in the wavelength range of approximately 400 to 800 nm) create a certain color effect and, in addition, in the invisible (e.g., ultraviolet and infrared) spectral regions t reflective or radiation-transmitting properties specific to a particular protective printing ink. If a document protected from forgery is attempted to be faked using, for example, a color copier, then, in principle, a similar approach allows reproducing the visible color gamut of the sealed surface area. However, since particles of commercially available inks do not possess spectral characteristics characteristic of special protective printing inks in invisible spectral regions, fake securities and documents, in general, can be detected by appropriate measurement of their reflection or transmission characteristics of the object in the invisible spectral regions (RU No. 2268494, 2004).

The term “securities and documents” hereinafter refers to objects that represent, for example, monetary value or a certain authority and, therefore, they should not be made by unauthorized persons. For this reason, they have signs that are not easy to produce (first of all, copy) and the presence of which is evidence of authenticity, i.e., the fact of the production of a valuable document by an authorized organization.

An important class of security features of such securities and documents are optically recognizable features, which include, first of all, features that use phosphors, which, when irradiated with optical radiation of a certain range, emit luminescent (in particular, fluorescent or phosphorescent) radiation, i.e., they luminesce with a given wavelength and characteristic spectrum.

In this case, by optical radiation is meant electromagnetic radiation in the ultraviolet, visible or infrared regions of the electromagnetic spectrum.

For authentication, a security paper or document may be irradiated with suitable optical radiation. In this case, using an appropriate sensor device, it is possible to check whether optical radiation excites luminescence in predetermined places on a security paper or document. For this, the optical radiation emanating from the object being studied (detected) is subjected, for example, to spectral analysis. Such verification should occur, firstly, rather quickly, and secondly, should be provided with relatively simple and inexpensive hardware so that the devices through which authentication is performed (in particular) by luminescent signs are as possible more compact, but at the same time they would have a spectral resolution and sensitivity sufficient to recognize the presence, for example, of a characteristic luminescence spectrum (RU, No. 2409862, 2011).

In principle, for research, you can use the light of lighting devices used in the room. However, the result of such studies, focused on the use of such light, are too large errors due to significant fluctuations in the light properties of the aforementioned lighting devices.

Therefore, for research, devices are used that have:

- lighting means, providing irradiation with optical radiation with desired properties, at least part of the area of the investigated object, which is governed by the size of the working area of the device;

- a device (sensor) for detecting optical radiation emanating from or through a region of the object under study.

Although it is possible to use light sources, such as, for example, halogen lamps, to illuminate (irradiate) the object under study, they consume too much power compared with the radiation power in the required spectral range and, therefore, require sufficiently intensive cooling. In addition, the disadvantage of these light sources is that they are characterized by a relatively short service life. In addition, these light sources are quite large (RU, No. 2421817, 2011).

Closest to the claimed technical solution is a device for detecting security features in the process of authenticating securities and documents containing:

- a lighting device made in the form of a LED generator of electromagnetic radiation of the infrared range and functionally being a source of radiation in a pulsed mode moving across the measuring window of the object under study;

- a multichannel photodetector system located opposite to the lighting device and including at least: a photodetector generated, during irradiation, by the corresponding sections of the studied object of infrared electromagnetic radiation, made in the form of a linear matrix of radiation receivers, which is functionally a means of recording the generated irradiation; radiation, as well as a processing unit that is functionally a means of verifying the authenticity of the object under study based on processing, digitalization and subsequent comparison using the yes-no algorithm of the values of the specified characteristic parameters of the generated, during the irradiation, corresponding sections of the investigated object of infrared radiation recorded by said photodetector, with reference values corresponding to the original object, which store in the memory unit, (EP-OS, No. 0537513).

The disadvantages of this prior art device include the complexity of the design and the relatively large overall parameters.

Based on the foregoing, the present technical solution was based on the task of creating such a device that would allow for small dimensions and simplicity of design to provide reliable verification of as many different physical properties of the studied object as possible, such as banknotes.

In addition, the claimed technical solution was based on the task of expanding the arsenal of technical equipment designed to control the authenticity and identification of securities and documents.

Accordingly, the technical result consists in the implementation of this purpose (clause 9.7.4.3. (1.2) of the "Administrative Regulations ..." 2008), i.e. in the implementation of the process of authenticity control and identification of securities and documents while ensuring the compactness of the device, the simplicity of its design while maintaining its speed and ensuring the necessary resolution (reliability) of detection.

The technical result is achieved by the fact that in the device for detecting security features in the process of authenticating securities and documents containing: a lighting device, made in the form of a LED generator of electromagnetic radiation of the infrared range and functionally being a source of radiation in a pulsed mode moving across the measurement window of the investigated object; a multichannel photodetector system located opposite to the illuminating means and including at least: a photodetector generated by irradiating with the corresponding sections of the studied object of infrared electromagnetic radiation, made in the form of a linear matrix of radiation receivers, which is functionally a means of detecting the generated radiation during irradiation; radiation, as well as a processing unit, which is functionally a means of verifying the authenticity of the object under study based on processing, conversion, mainly into digital form and subsequent comparison using the yes-no algorithm, of the values of the specified characteristic parameters generated by irradiation corresponding to sections of the investigated object of infrared radiation recorded by the said photodetector, with reference values corresponding to the true volume cta that are stored in the memory unit according to the invention, the electromagnetic radiation generator is formed as a structurally composed of the same type, preferably identical to the linear array of LEDs, which has a length not less than the width of the detected portion of the test object; the linear matrix of the photodetector also consists of the same type, mainly identical photodiodes, each of which is located on the opposite, relative to the photodiodes, side of the object under study, while adjacent photodetectors of the photodetector are paired with each other with the possibility of detecting the object under study simultaneously on all the detection channels formed by them ; and as the values of the specified characteristic parameters of the luminescence radiation generated by the corresponding sections of the surface of the object under study, that is, the response recorded by the photodetector, the damping characteristic of the luminescence radiation mentioned above and, through this characteristic, the topology of the placement of the luminescent security features on the studied object are used.

It is optimal that the main optical axes of the light and photodiodes of the electromagnetic radiation generator and the photodetector system, respectively, intersect in pairs in zones adjacent to the plane of placement of the object under study.

It is also acceptable that the main optical axes of the photodiodes of the photodetector system and the optical beams formed by the LEDs of the electromagnetic radiation generator intersect in pairs in zones adjacent to the plane of placement of the object under study.

It is advisable that the optoelectronic components of the lighting means are functionally organized with the possibility of their inclusion at maximum power only in that case. when the edge of the moving object under study enters the zone of the field of view of the photodetector, limited by the measuring window.

An analysis of the prior art by the applicant, including a search by patent and scientific and technical sources of information and identification of sources containing information about analogues of the claimed invention, made it possible to find that no analogues were found that are characterized by signs and relationships between them that are identical to all the essential features of the claimed technical solution, and the prototype selected from the identified analogues, as the closest analogue in terms of the totality of features, made it possible to identify the essential set (with respect to the Riva applicant technical result) distinguishing features in the claimed object set forth in the claims.

Therefore, the claimed technical solution meets the condition of patentability "novelty" under the current law.

In order to verify the conformity of the claimed technical solution to the requirement of the patentability condition “inventive step”, the applicant conducted an additional search of similar solutions known from the prior art in order to identify features that match the distinctive features of the claimed technical solution, the results of which show that the claimed technical solution does not follow ( for a specialist) explicitly from the prior art, since the influence of the prior art (as determined by the applicant) does not reveal transformations provided for by the essential features of the claimed technical solution for achieving the technical result perceived by the applicant.

In particular, the claimed technical solution does not provide for the following transformations of the known prototype object:

- addition of a well-known object by any well-known sign, attached to it according to known rules, to achieve a technical result, in respect of which the influence of such additions is established;

- replacement of any sign of a known object with another well-known sign to achieve a technical result, in respect of which the influence of such a replacement is established;

- the exclusion of any sign of a known object with the simultaneous exclusion due to the presence of this sign of the function and the achievement of the usual result for this exclusion;

- an increase in the number of similar features in a known object to enhance the technical result due to the presence of just such signs in the object;

- the implementation of a known object or part of it from a known material to achieve a technical result due to the known properties of the material;

- the creation of an object that includes known features, the choice of which and the relationship between them are based on known rules and achieved, while the technical result is due only to the known properties of the features of this object and the relationships between them.

Therefore, the claimed technical solution meets the requirement of the patentability condition "inventive step" under applicable law.

Further, the claimed invention is described in more detail in combination with preferred options for its implementation with reference, respectively, to the accompanying graphic materials, which illustrate the following.

Figure 1 is a General view of the claimed object (side view).

Figure 2 - General view of the claimed object (left view of figure 1).

Figure 3 - section aa in figure 2.

Figure 4 is a General view of the claimed object (axonometry).

5 is a block (receiver and control of the claimed object, General side view).

Fig.6 is a section bB in Fig.5 (cover 9 upper conditionally not shown).

Fig.7 is a section bb in Fig.6.

Fig - block (emitter of the claimed object, General view in plan, cover pos.16 conditionally not shown).

Fig.9 is a block (emitter of the claimed object, left view)

Figure 10 is a cross-section GG of Fig.8 (option 1 with glass 3).

11 is a cross section GG of Fig.8 (option 2 with a prism 3).

Fig - scheme (optical principle of the claimed object).

Fig.13 is a view D of Fig.12.

Fig. 14 is a diagram of the mutual arrangement of oppositely located photo and LEDs according to claim 2.

Fig - graph of the decline of the pulse of the lighting means during one measurement cycle (measurement at one "point" - area).

Fig. 16 is a grid of “points” (areas) for measuring sections of a security or other document (in particular, a banknote).

The constituent structural components of the device for detecting security features in the process of authenticating securities and documents in graphic materials and hereinafter are indicated by the following positions.

1 - block (receiver and control).

2 - block (emitter).

3 - glass (or deflecting prism, 11).

4 - bracket (left).

5 - bracket (right).

6 - screw (fixing).

7 - board (control).

8 - board (photodetectors).

9 - a cover (top).

10 - housing (photodetector).

11 - holder (boards 8 of the photodetector).

12 - screw (fixing).

13 - screw (fixing).

14 - board (illuminators).

15 - case (emitter 2).

16 - cover (emitter 2).

17 - insert (under the glass 3 of figure 10).

18 - insert (under the prism 3 of Fig.11).

19 - LED (for example, IR 940).

20 - photodiode (e.g. BPV10NF)

21 - object (being investigated).

22 - plane (passing the object 21).

23 - pulse (signal lighting means).

24 - recession (ideal pulse signal lighting means).

25 - recession (pulse signal of the lighting means in the presence of a response - luminescence radiation).

26 - recession (pulse signal of the lighting means in the absence of response - luminescence radiation).

27 - points (i.e., zones detected by the studied object with the presence of a response - luminescence radiation).

28 - points (i.e., zones detected by the studied object with no response - luminescence radiation).

29-35 - channels (optical photodetector system for recording the response from the studied object in the light passing through the studied object).

A device for detecting security features in the process of authenticating securities and documents has the following physical structure.

The claimed device contains: a lighting device (emitter unit 2 with a board 14 of illuminators located in its housing), made in the form of a LED generator of electromagnetic radiation in the infrared range and functionally as a radiation source in a pulsed mode moving across the measuring window (protected by glass 3 of Fig. 10 or prism 3, 11) of the investigated object 21; a multichannel photodetector system (receiver and control unit 1 with a control board 7 and a photodetector board 8 located in the housing 10) located opposite to the lighting means and including at least a photodetector generated by irradiation with corresponding sections of the studied object of infrared electromagnetic radiation, made in the form of a linear matrix of radiation receivers, which is functionally a means of registering the radiation generated during the irradiation; and also a processing unit which is functionally a means of verifying the authenticity of the object under study, which is functionally a means of verifying the authenticity of the object under study, based on processing, conversion, mainly into digital form, and subsequent comparison using the yes-no algorithm of the values of the specified characteristic parameters of the generated, by irradiation, corresponding sections of the investigated object of infrared radiation detected by said photodetector, with reference values corresponding to the genuine object, which e stored in the memory unit.

The emitter unit 2 (with cover 16) and the receiver and control unit 1 (with cover 9) are combined into a rigid structure (with the possibility of forming a technological gap between them to pass the test object 21 along plane 22) by means of brackets 4 and 5, also designed for fastening the claimed device to the corresponding technological equipment.

The electromagnetic radiation generator is structurally formed in the form of a linear matrix consisting of the same type, mainly identical LEDs 19, which has a length not less than the width of the detected area of the investigated object 21. The linear photodetector matrix also consists of the same type, mainly identical photodiodes 20, each of which is located with the opposite, relative to the LEDs, side of the studied object 21. In this case, the adjacent photodiodes 20 of the photodetector are paired with each other with the possibility of detecting the investigated object 21 simultaneously on all the channels 29-35 of detection formed by them. As the values of the specified characteristic parameters of the luminescence radiation generated by the corresponding surface sections of the investigated object 21, that is, the response recorded by the photodetector generated, the damping characteristic of the luminescence radiation mentioned above and, by means of this characteristic, the topology of the placement of the luminescent security features on the studied object 21 are used.

It is optimal that the main optical axes of the light and photodiodes 19 and 20, respectively, of the electromagnetic radiation generator and the photodetector system, respectively, intersect in pairs in zones adjacent to the plane of placement of the investigated object 21.

This feature can be implemented by tilting the main optical axes of the LEDs 19 relative to the horizontal plane (see Fig. 14).

It is also acceptable that the main optical axes of the photodiodes 20 of the photodetector system and the optical beams generated by the LEDs 19 of the electromagnetic radiation generator intersect in pairs in zones adjacent to the plane of placement of the object under study 21, which can be structurally ensured by using a deflecting prism 3 (see Fig. .eleven).

These particular features exclude the negative effect (illumination) of the photodiodes 20 by the light beams of the LEDs 19, which improves the quality of detection of the investigated object 21.

It is advisable that the optoelectronic components of the lighting device be functionally organized with the possibility of their inclusion at maximum power only when the edge of the moving object under study 21 enters the field of view of the photodetector, limited by the measuring window.

The principle of operation of a device for detecting security features in the process of authenticating securities and documents from a physical point of view is as follows.

The following is considered, first of all, the detection of banknotes in the infrared region of the spectrum, however, the above example does not in any way limit the range of operational capabilities of the claimed technical solution.

The claimed object monitors the presence of machine-readable security features (in particular, fluorescent labels) used to protect securities and documents, such as banknotes.

The principle of operation of the claimed device is based on the registration of special protective features (which the test object 3 is equipped with) through the optical channels 29-35 of the photodetector located in the measuring window, and comparing their (i.e., protective features) relative position and intensity of the luminescent radiation with bit (reference) mask laid down by the manufacturer, for example, in the memory block of the CCM (counting and sorting machine) or directly in the memory block of the declared object.

In the context of the present technical solution, “measuring window” should be understood to mean a section or part of a structure representing a gap through glass 3 (or deflecting prism 3, see FIG. 11), through which the device irradiates and detects the object under study 21.

The registration of security features is carried out when passing the object under investigation 21 (for example, banknotes) opposite to the measuring window according to the following algorithm:

- upon receipt from the CCM (counting and sorting machine) of a signal about the location of the beginning of the investigated object 21, the lighting means of the claimed device begin to illuminate the object 21 in a pulsed mode with IR radiation;

- after each pulse of illuminating means, photodetector means measure the decay of the pulse signal 23, i.e., the response (Fig. 14) generated by the light passing through (i.e., penetrating the object 21 under study), luminescence radiation. One such measurement cycle can be considered a measurement at one “point” (zone). At the same time, the response is recorded by the family (according to Fig. 13 and Fig. 15) by the optical channels 29-35 of the photodetector (i.e., over the entire width of the detected area of the object under study 21, which is in the field of view of the measuring window);

- to determine the presence of a signal, the tangent of the angles of decay of the luminescence radiation (i.e., the angles "α" and "β", Fig. 14) is calculated.

In the case of the presence of a protective feature (luminescence radiation), the photodetector detects a slower decay of the luminescence radiation pulse 23 due to the presence of a luminescent substance with predetermined absorption-radiation spectra (see Fig. 14, pos. 25). A certain number of "points" are fixed on the banknote (Fig. 15). The information obtained allows us to determine the location and intensity of all responses (luminescence radiation), and then compare with a bit (reference) mask defined (individual) for each object 21 (in particular, the banknote value) and decide on compliance (or non-compliance) the investigated object 21 according to this particular security feature the condition of authenticity.

Information on the compliance (or non-compliance) of the registered features with the reference is transmitted to the CCM control unit of a higher level., Where the banknotes are sorted according to the condition of their authenticity. This block, based on the information received, makes a decision on the further use of the detected object. If necessary, this decision can be made directly by the signal processing unit of the claimed device.

When using the claimed device as a composite CCM module, the control unit can direct the detected object (taking into account the technical capabilities of the CCM, either into the receiving tray for stacking, or into a shredder for destruction, or into other functional components of the CCM.

The lighting means can directly emit infrared radiation, or in front of it, you can install a filter 4, which transmits only infrared radiation.

A photodetector may initially be sensitive only to infrared radiation emitted by a luminescent substance, or an optical filter can be installed in front of the photodetector that passes only infrared radiation of the corresponding spectrum in its direction.

In addition to them, or instead of them, additional optical systems, such as lenses, can be provided at the filter installation site in order to ensure, for example, special focusing of optical radiation at the place of its incidence on the object under study 21 or on the photodetector.

The processing unit may be, for example, a microprocessor commutatively coupled to a memory unit, which, in this case, may have volatile and non-volatile regions. In the non-volatile region of the memory block, first of all, the above-mentioned reference values of the recorded features are stored.

In the processing unit of the measurement results, an analog-to-digital converter can be provided that transforms the output signal of the photodetector into digital form.

Linear arrays of photodiodes are structurally organized with the possibility of arranging adjacent photosensitive elements tightly with each other. That is, in the optimal embodiment, the photosensitive elements should be located, for example, on a common base, so that their edges are adjacent to each other. The advantage associated with this arrangement of photosensitive elements with their tight arrangement is the ability to maintain at a minimum level possible parallactic errors due to the different positions of the photosensitive elements. That is, adjacent photosensitive elements "scan" at approximately the same angle the same area of the detected object.

At least one diaphragm may be provided between the object and the radiation receiver, which allows setting or adjusting the sizes of the area detected on the object 21, in which the radiation emitted from the object 21 is detected by the radiation receiver.

Such a solution makes it possible to obtain a particularly compact and inexpensive device that allows a simple way to purposefully set the dimensions of the area being checked, for example, by varying the size of the aperture opening, as well as by varying the distance from it to object 21, respectively, to the reflected photodetector. In this case, the distance from the diaphragm and its type is preferable to be selected so that the area being checked at object 21 has sufficiently large dimensions compared to the dimensions of irregularities at object 21 (such as, for example, jammed folds), but at the same time it is quite small in comparison with those parts of the surface of the object 21, within which it is necessary to identify a special spectral characteristic.

As the focusing optical system, it is preferable to use self-focusing lenses. In the context of the present technical solution, self-focusing lenses are understood to mean cylindrical optical elements made of a material that has a refractive index decreasing from the optical axis of the cylinder to its side surface. Due to the use of such a lens, a monitored section of the object 3 on the photodetector in a 1: 1 scale is provided that does not depend on the distance between the object and the radiation receiver and does not require adjustment.

In General, the claimed device allows to obtain a compact, structurally simple and inexpensive design due to the rejection of the use of additional, increasing the spectral resolution of optical structures, such as, for example, prisms, diffraction gratings, or similar elements. Another advantage is the extremely low cost of aligning the individual components of the proposed device with their respective performance.

Conducted operational tests of the claimed object showed its industrial applicability for such indicators as resolving power and reliability of detection of the studied objects 21.

Thus, the above information indicates the fulfillment of the following set of conditions when using the claimed technical solution:

- the object embodying the claimed technical solution, when implemented, can be implemented as a device for controlling the authenticity of securities and documents;

- for the claimed object in the form described in the independent clause of the formula below, the possibility of its implementation using the means and methods described above or known from the prior art on the priority date is confirmed;

- the object embodying the claimed technical solution, when implemented, is able to ensure the achievement of the technical result perceived by the applicant.

Therefore, the claimed subject matter meets the patentability requirements “industrial applicability” under applicable law.

Claims (4)

1. A device for detecting security features in the process of authenticating securities and documents, comprising: a lighting device made in the form of a LED electromagnetic radiation generator of the infrared range and functionally being a source of radiation in a pulsed mode moving across the measurement window of the object under study; a multichannel photodetector system, located opposite to the lighting device and including at least: a photodetector generated by irradiating the corresponding sections of the studied object of infrared electromagnetic radiation, made in the form of a linear array of radiation receivers, which is functionally a means of recording the said radiation generated during irradiation, as well as a processing unit which is functionally a means of verification of the authenticity of the object under study on the basis of processing, conversion, mainly into digital form, and subsequent comparison using the yes-no algorithm of the values of the specified characteristic parameters generated by irradiating the corresponding sections of the object under study with infrared radiation recorded by the aforementioned photodetector, with reference values corresponding to the genuine an object that is stored in a memory unit, characterized in that the electromagnetic radiation generator is structurally formed form consisting of the same type, preferably identical to the linear array of LEDs, which has a length not less than the width of the detected portion of the test object; the linear matrix of the photodetector also consists of the same type, mainly identical photodiodes, each of which is located on the opposite side of the investigated object with respect to the photodiodes, while the adjacent photodetector of the photodetector is paired with one another with the possibility of detecting the object under study simultaneously on all the detection channels formed by them; and as the values of the specified characteristic parameters of the luminescence radiation generated by the corresponding sections of the surface of the object under study, that is, the response recorded by the photodetector, the damping characteristic of the luminescence radiation mentioned above and the topology of the placement of the luminescent security features on the object under study are used. 2. The device according to claim 1, characterized in that the main optical axis of the light and photodiodes of the electromagnetic radiation generator and the photodetector system respectively intersect in pairs in zones adjacent to the plane of placement of the test object. 3. The device according to claim 1, characterized in that the main optical axis of the photodiodes of the photodetector system and the optical beams formed by the LEDs of the electromagnetic radiation generator intersect in pairs in zones adjacent to the plane of placement of the object under study. 4. The device according to claim 1, characterized in that the optoelectronic components of the lighting means are functionally organized with the possibility of their inclusion at maximum power only when the edge of the moving object under study is included in the field of view of the photodetector, limited by the measuring window.

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