RU2123722C1 - Method for checking validity of securities - Google Patents

Abstract

FIELD: image recognition equipment. SUBSTANCE: method involves exposition of security item, which is printed using paint with normalized spectrum for absorption, passing and reflecting light in given bandwidth, reading reflected light by photodetector and comparison scanned image of security item under investigation to reference image of authentic security item. Exposition is performed sequentially in several band-widths within which range said paint has normalized spectrum for absorption, passing and reflecting light. Then integral color image of security item under investigation is generated as halftone scale which differ from scale of other intermediate images but which color is equal to halftone scale of corresponding reference intermediate image of authentic security item within corresponding range of visible light. EFFECT: increased efficiency and validity of checking. 2 cl

Description

 The invention relates to techniques for image recognition and can be used in the development and creation of devices that can determine the authenticity of securities, the image on which is printed using ink, with the ability to selectively absorb, transmit and reflect the radiation incident on it.

 A known method for distinguishing and determining the reliability of a printed pattern, according to which a banknote during its movement is illuminated with white light, and the light reflected from it enters the photosensor through a filter in which red and green stripes alternate. The signal from the sensor is integrated for each color, and then compared with the standard (application N 57-36628 B, Japan, announced in 1974, published in 1982, MKI G 07 D 7/00).

 Also known is a method and device for recognizing banknotes, in which along the direction of movement of the banknote a series of photosensors is installed to detect radiation transmitted through the banknote, each of which has its own passband. The signal received from the output of each sensor individually is then compared with a reference (application N 56-24685 A, Japan, announced in 1979, published in 1981, MKI G 07 D 7/00).

 In addition, a method and device for optical testing of banknotes are known, in which the dependence of the reflection coefficient in the red and blue ranges of visible light on the properties of the pattern of the banknote printed in a printing manner, as well as on the properties of the pattern of the banknote copied on the copier, is used. Why the controlled banknote is illuminated at a certain angle to its surface and the reflected and transmitted light is recorded (PCT application N 91/03031, declared in 1989, published in 1991, MKI G 07 D 7/00).

 Although the above known control methods and devices that implement them allow you to control the authenticity of securities, they have a significant drawback, namely they have low efficiency, since they do not provide the ability to obtain a visual integrated (integrated) assessment of the authenticity of the pattern on a security that takes into account the results of control as within each individual interval of light wavelengths of the absorption spectrum, and complex (integrated) over all controlled intervals of length n light waves together. The inability to obtain such a comprehensive (integrated) assessment of the authenticity of the pattern on the security using the above known methods and devices for their implementation does not allow to obtain a sufficient level of information content of the research results themselves, allowing us to draw an indisputable conclusion about its compliance (non-compliance) with the standard, which significantly reduces the effectiveness and reliability of authentication results. In other words, the known methods and devices for their implementation allow, in principle, to unambiguously establish the correspondence (mismatch) of the controlled parameter within each individual interval of light wavelengths of the absorption spectrum to its standard, and as for the complex (integrated) assessment, taking into account the real technological spread of the controlled parameters both within each individual wavelength interval, and for all other controlled wavelength intervals together, then obtaining such a com they do not provide a complex (integrated) characteristic with sufficient information for an expert assessment.

 To solve the stated problem, that is, to increase the efficiency and reliability of the results of authentication, a new method of authenticating a security is claimed, which includes irradiating its surface with a light source, receiving a light sensor reflected from it, and comparing the resultant light received light energy of a complex (integrated) color visual image of a controlled security with a reference complex (integrated) color visual image of an authentic color paper. In the claimed new method for checking the authenticity of a security, in contrast to the known methods, irradiation of a pattern printed on its surface using the aforementioned ink is performed by a light source with a normalized emission spectrum in series, within each individual interval of wavelengths of light within each of which the above ink selectively absorbs, transmits and reflects the radiation incident on it, while the necessary amount of information about the transformation of the spectral composition of the incident о radiation paint is obtained in the form of a complex (integrated) color visual image of a controlled security obtained by adding (combining) all previously obtained intermediate intermediate visual images of the corresponding different homogeneous (spectral) colors, each of which is obtained as a result of the reception of reflected light energy by the photosensor from the surface of the controlled security when it is irradiated within one of the corresponding light wavelength intervals, and each individually An intermediate reference visual image of a security is obtained in the form of a gradation of one of the homogeneous (spectral) colors, which differs in color from each of the gradations of homogeneous (spectral) colors used to image other intermediate visual images of the controlled security and which is completely identical in color to the reference intermediate visual image in the form of a gradation of one of the homogeneous (spectral) colors obtained when the photosensor receives the reflected light energy from the surface of an exemplary valuable paper within a similar range of light wavelengths. At the same time, the arising sensation of color during the visual perception of a complex (integrated) color visual image of a controlled security provides the ability to analyze both qualitatively - by color (the presence of colors and shades, as well as their saturation), and quantitatively, fixing the brightness of the reflected radiation, t. E. The expert gets the opportunity to analyze the degree of similarity and discrepancy of two apparently similar visual images (drawings), taking into account even a slight discrepancy in their parameters and some x nuances characterizing features of manufacturing techniques investigated the security. Depending on the complexity of the task to be solved, the expert has the opportunity to reduce or increase both the number of controlled intervals and the width of each of them, as well as move any of the above intervals to one side or another within the entire range of light waves, which ensures substantially better conditions , allowing to obtain the necessary and sufficient amount of information for drawing up a scientifically based conclusion on the authenticity of the investigated pattern on the security at the level of the relevant state arstvennyh supervisory bodies.

 If the working frequency band of the used photosensor does not cover all the controlled parts of the spectrum with the normalized value of the light reflection coefficient, for example, from the infrared to the ultraviolet regions of the spectrum, then the intermediate visual image of the controlled security for each part of the spectrum is first obtained in the form of gray gradation, using, for example, a black-and-white video camera as a photosensor, and then the resulting gray gradation is replaced by a similar gradation of the corresponding uniform o (spectral) color. The need to obtain an intermediate image at first in the form of a gradation of gray with its subsequent conversion to a similar gradation of a homogeneous (spectral) color in some cases can be caused by the fact that the working frequency band of a color video camera is substantially narrower than that of black and white, therefore using a color video camera it is not always possible to obtain an intermediate visual image for all parts of the spectrum when conducting a security authentication of a security.

 There are both similarities and differences between the complex (integrated) color visual image of a controlled security and the color pattern printed on the surface of the banknote. The main difference between these two outwardly similar patterns is that the choice of color in the pattern printed on the security is determined mainly by the artistic intention of the author of this pattern, but the choice of a color on a complex color visual image at the initial stage is a conditional technical parameter associated with the selection of a certain range of light waves emitted by a light source during research. After a part of the emitted light energy is reflected from the surface of the security and is received by the photosensor, a signal in the form of a one-color gradation will be received at its output. This characteristic contains information about the artistic image of the drawing (the quantitative distribution of paint on the surface of the banknote), as well as the ability of the applied paint to selectively absorb, transmit and reflect radiation in the studied range of light wavelengths (intermediate color visual image). After adding (combining) all the intermediate images obtained for the controlled security, a new color visual image will be obtained, which allows a comprehensive (integrated) assessment of the authenticity of the pattern printed on the security, since it carries the information of both a single intermediate color visual image and the resulting, reflecting the mutual influence of each other all intermediate color visual images.

 To implement the proposed by the applicant and the authors of a new method of authenticating a security printed with ink with a normalized value of the reflection, absorption and transmission coefficients of light, the latter must be irradiated with a light source whose radiation wavelength is consistent with the wavelength of the controlled spectrum interval. If there are several controlled intervals of light wavelengths and they are located in different places over the entire range of light waves, then the surface of the security will need to be irradiated as many times as there are controlled intervals of light wavelengths, and the interval of wavelengths of the light source radiation must be coordinated with the interval each time wavelengths of each individually controlled portion of the spectrum. Since genuine securities of the same denomination have the same pattern printed with the same ink having a normalized light reflectance, and they are all irradiated from the same light source, the amount of security reflected from the surface the light energy of all genuine controlled papers of the same series will be almost constant. If the controlled security turns out to be fake (a mismatch in the pattern or properties of the paint, paper, etc. used for its manufacture), then upon irradiation the amount of reflected light energy and its distribution on the surface of this fake security under the same initial conditions will differ in that or the other side in comparison with the results of genuine (reference) irradiation.

The radiated light energy, partially reflected from the surface of the controlled security, is fed to the input of the photosensor (color or black and white video camera), which converts it into an intermediate visual image, which is a gradation of monochrome or gray. If the intermediate visual image for the above reason will be a gradation of gray, then it will then be converted into a similar gradation of monochrome. When choosing a gradation color for each intermediate visual image, the following conditions must be followed:
- the intermediate visual image in the form of a one-color gradation for each part of the spectrum should have a different color than other colors used in other gradations of the same color for the image of intermediate visual images of other controlled parts of the spectrum of the same controlled security;
- intermediate visual images in the form of a gradation of the same color in the same portion of the spectrum of both the controlled security and the model should have the same color.

 The conversion of gray gradation to a similar one-color gradation can be carried out, for example, using a computer as such a converter.

 To obtain a complex (integrated) visual image, it is necessary to add (combine) all the intermediate images into a single generalized visual image, which will then be the desired complex multicolor visual image of the image depicted on the surface of the controlled security, allowing it to be distributed over the entire surface of this drawing quantitative and qualitative assessment of both the drawing itself and the paint used to image it. The operation of adding (combining) the resulting intermediate visual images can be performed using a color monitor or color printer. Then, the complex (integrated) visual image of a controlled security obtained as a result of the above addition (combination) of intermediate visual images is visually compared with a standard obtained in a similar way, but always with a genuine security. The operation of comparing a complex (integrated) visual image of a controlled security with a standard can be carried out visually by showing them simultaneously on a color monitor screen or printing them using a color printer on paper. Using high-quality technology to obtain a conditionally color image of a pattern printed on a security paper and the amazing ability of the human eye to see both the similarities and the difference between two color samples with all possible color deviations in one direction or another in all the smallest details, one of which is the standard and another - by a generalized color visual image of a controlled security, it is possible to determine with very high reliability the similarities and differences of the controlled pattern to valuable paper with the standard.

 In contrast to the known ones, the claimed control method allows not only to give an unambiguous answer "genuine security" or "not genuine security", but also to give a conditional measure of such a coincidence, as well as accompany this information with a detailed scientific and technical justification with all possible nuances, and this in itself allows it to be used in the examination of super fakes at the highest state level, where the role and opinion of the expert (person) is to a large extent a determining factor in making an eye final determination of authenticity. In this case, for the first time, an expert has the opportunity to see with his own eyes through a colored visual image the presence of protective features invisible in the usual sense in a controlled security, and also to analyze the real degree of similarity and difference of these signs with the standard. The proposed method of authenticity control is designed to conduct research on the highest level of fakes, which allows not only to establish their presence, but also to solve a number of other problems associated with the disclosure of the features of the manufacturing technology of such fakes, as well as materials used for their manufacture.

 The claimed method of controlling paper was developed as part of one of the research works. Based on its results, a methodology and technology for authenticity control was developed, and a prototype of a device that implements the claimed method was manufactured. The tests of the prototype of the above device yielded positive results and fully confirmed the possibility of using the claimed method for the examination of super-counterfeit securities at the highest level.

Claims (2)

 1. A method for controlling the authenticity of a security paper printed with a paint with a normalized absorption, transmission and reflection spectrum in a number of light wavelength intervals, including irradiating its surface with a light source, receiving photo sensors of the light energy reflected from it, and comparing the result obtained by receiving the photosensor reflected light energy of the visual image of a controlled security with a reference visual image of a genuine security, characterized in that the irradiation of the surface of the controlled security The paper is carried out by a light source with a normalized emission spectrum in series, within each individual interval of light wavelengths, within the boundaries of each of which the above ink has a normalized absorption, transmission and reflection spectrum of light, while the integrated color visual image of the controlled security is obtained by combining all intermediate visual images, each of which is obtained as a result of the reception by the photosensor of reflected light energy from the surface of the counter an irreplaceable security when it is irradiated within one of the corresponding light wavelength intervals, and each separately an intermediate visual image of the security is obtained in the form of a gradation of a uniform color, different in color from each of the gradations of a uniform color, used to image other intermediate visual images of a controlled security paper, and completely matching in color with a gradual uniform color of the corresponding reference intermediate visual image obtained when taking f todatchikom light energy reflected from the surface of a model of a security within the same interval of light wavelengths.  2. The method according to claim 1, characterized in that the intermediate visual image of the controlled security for each interval of wavelengths of light is preliminarily obtained in the form of a gradation of gray, and then it is replaced with a similar gradation of a uniform color.