RU2137197C1 - Information carrier for protection of articles with identification contrast image against faking - Google Patents

Abstract

FIELD: detection of authenticity of bank notes, securities, credit documents, standard labels of articles. SUBSTANCE: one label from set of protection labels is designed as image which identical to identification contrast image of article. Information carrier has base, which has region which is made from magnetic material, shaped as strip and is covered from visual perception by code data, which are provided as group of protection labels for reading code using detection. One protection label is designed as image which is subjected to cryptographic modulation using key k, of at least part of identification contrast image of article. Another protection label is made from material which has stochastic mix of at least two stable isotopes with different atomic weights. These label is detected by means of unit for detection of reference stochastic values for ratio of weight of isotopes with different atomic weights. EFFECT: optical detection of information field of information carrier. 2 cl, 1 dwg

Description

 The invention relates to means of protecting products from counterfeiting and can be mainly used, for example, to determine the authenticity of banknotes, other securities and credit documents, as well as standardized signs of conformity.

 Currently, direct financial losses of developed countries due to counterfeiting (unauthorized issuance and large-scale introduction into circulation) of banknotes, credit documents and other securities, as well as standardized signs of conformity are significant amounts. This is due to the fact that the current level of development of computing, analytical and multiplying equipment allows reproducing with a high degree of identity almost any security paper (including the code information embedded in it) in any quantity at a relatively low cost.

 This problem is especially acute in cases of mass production of products, for example, bank notes (banknotes) and signs of conformity of goods, when the cost of their manufacture and protection from counterfeiting of these products should be minimal.

 In addition, in this case, the security label (made on the information carrier) should be quickly detected by means of inexpensive and affordable technical means for a wide range of users.

 Currently, there are various methods and means of protection against counterfeiting of products, in particular, banknotes and other securities and documents.

 For a selected group of protected products, for example, securities, the applied security elements (tags) are usually divided into three groups: prepress, print and postpress.

 Prepress protective elements are paper composition, watermarks, metallic thread, fibers colored and glowing in ultraviolet rays, confetti, etc.

 Printed protective elements include elements that provide for the implementation of graphic image reproduction methods, including micro-printing, combined and code patterns, etc .; elements realized directly by printing methods, including by means of deep, high, flat metallographic and other printing methods; elements providing methods for implementing (creating) optical effects; printing inks used.

 A set of post-print security elements may include embossing, film coating, labeled elements, magnetic strips (threads), etc.

 A significant part of the known methods and means of protection against counterfeiting are methods of protection by means of metal protective labels. Moreover, the mark can be formed both by direct application of the mark material (for example, in the form of paint) on the protected product, and by applying to the said product separately means made of the mark material, for example, in the form of a strip (thread).

 A known method of protecting valuable products from counterfeiting, according to which the storage medium is formed by pressing strips of magnetic material into the paper base of the product. The authenticity of a product, for example, a security, is determined by means of a magnetic detector detecting a change (gradient) in magnetic field strength (EP, N 005720, class G 07 D 7/00, 1982).

 The disadvantages of this known from the prior art means of protecting securities from counterfeiting should be attributed to its lack of reliability, since the manufacture of a strip of magnetic material accessible to a wide range of people does not represent any technical complexity for a specialist and does not require significant material costs.

 Consequently, the degree of probability of counterfeiting securities and other products protected in accordance with the protection method under consideration is quite high.

The prior art also knows a method of protection against counterfeiting of valuable products, in particular banknotes, securities and other documents, according to which an isotope indicator based on the stable isotope osmium-187 ( ¹⁸⁷ Os) or it (stable isotope osmium- 187) a chemical compound in which (a chemical compound) provides constant stabilization (in time and space) of the magnetic orientation of the spins (intrinsic momenta of the momenta) of the system of elementary particles that make up the osmium-187 atoms.

 An information carrier, including a protective label, is formed with the possibility of monitoring the presence of this label (when detecting) on the protected product by a physical analysis method for isotopic effects, in particular, for the magnetic properties of osmium-187 nuclei by nuclear magnetic resonance (RU, patents N2074420 and N 2077072 Cl. G 07 D 7/00, 1997).

 The use (in the considered method and means of protecting products from counterfeiting) of the stable osmium-187 isotope in the form of a chemical compound of osmium-187 with a ferromagnetic substance allows the use (in the detection process) of the internal magnetic fields of atoms reaching 500 T or more, because when interacting with the magnetic fields of the atoms of a ferromagnet, the magnetic fields of osmium-187 atoms are ordered in space. This makes it possible to obtain an NMR (nuclear magnetic resonance) signal, i.e. the effect of selective absorption of radiation of a certain radio frequency, without exposure to external magnetic fields of high power.

 A favorable (for the case under consideration) characteristic of osmium-187 is also that its core has a spin equal to 1/2; therefore, there is no electric quadrupole moment, which makes it possible to exclude electrical disturbances in the process of detecting a protective mark.

 To detect a known protective device on a protected product (i.e., a protective tag reproduced on an appropriate information carrier), a nuclear magnetic resonance spectrometer known in the art is used, in which, for the orientation of the magnetic fields of the atomic nuclei of the material under study (in particular, the security label material) superconducting magnets that create a magnetic field of up to 20 T.

 It should be noted that the aforementioned superconducting magnets constitute the dominant (main) part of the cost of the aforementioned NMR spectrometer.

 Detection in the case of using a osmium-187 compound with a ferromagnetic substance (material) as a protective label is also carried out by known methods and using means known from the prior art.

 In particular, when a “p / 2” radio frequency pulse generated by the detector is superimposed (in antiphase with the magnetic moments of the osmium-187 atomic nuclei), the spins of the osmium-187 atomic nuclei are “scattered”. At the next momentum “p” (of the same source of electromagnetic radiation in phase with the magnetic moments of the osmium-187 atomic nuclei), the spins of the osmium-187 atomic nuclei simultaneously return to their main oriented (stabilized by the magnetic influence of the atomic spins of the substances that are the ingredients of the compound under consideration) state .

 This makes it possible to detect by the means of a detector (including an NMR spectrometer) the so-called "spin echo" created (generated) by a system of elementary particles forming the osmium-187 atomic nucleus. Detection is carried out by triggering the device only on the osmium-187 nuclei with a resonant frequency of 107.5 MHz.

 The disadvantages of the above technical solutions, it is advisable to include the following.

 Reliable protection of a product protected from falsification (in particular, banknotes, securities or documents), according to the method described above, known from the prior art, for the means for its implementation is provided by using unique material as a security mark, the development of which requires such a level of technical means , material and labor costs, which can only be ensured by a state possessing modern nuclear technologies (including methods for separating the osmium-187 isotope from iysoderzhaschih and ultralean ores or from poor and ultralean waste process solutions).

 Indeed, the uniqueness of the material and the technology of its production provides a sufficiently high degree of protection for valuable products (including banknotes, securities, credit and other documents, as well as all other objects that require, due to their specific value, individual or large-scale protection) from forgery.

 However, it is precisely the uniqueness and technological complexity of the production of osmium-187 that limits its use in terms of large-scale protection of products from counterfeiting (for example, banknotes), since the cost of producing one banknote (and even more so the guest mark of conformity) can be commensurate with the nominal value of this banknote, and in some cases they can be significantly higher than the nominal value of the protected products, for example, for small banknotes or guest marks of conformity.

 If we take into account the fact that in the current conditions of market relations this unique material (osmium-187) can be acquired by the interested person in its pure form in the right amount by purchasing it (including illegally), as well as the fact that The technological process of forming an information carrier with a protective label based on osmium-187 (according to the invention under consideration) does not pose any difficulties and does not have technological know-how, and the fact that the minimum amount of osmium-187 is necessary for the guaranteed detection of the security label is 5 μg, it can be concluded that the person concerned can reproduce this security label, for example, on banknotes an unlimited number of times, and each illegally reproduced label will be absolutely identical to the reference, because the physicochemical properties of osmium-187, even obtained by different technological methods and from different sources will be absolutely identical.

 A known information carrier for protection against counterfeiting of products with an identifying contrast image containing a base having at least one section made of magnetic material with code information hidden from visual perception. The code information in the said area (made of magnetic material) is formed as a group of security labels for reading the code through detection (machine vision). The security tags in the group are made in the form of images that are cryptographically adapted by means of the corresponding key to at least part of the identification contrast image of the product (RU, 2070736, class G 06 K 19/08, 1996).

 The disadvantages of this known technical solution include the one-level degree of protection of the product from counterfeiting exclusively by encoding visually perceived (by the human eye) uncoded information (available on the product, for example, in the form of a bank check number) in the form of a hidden (invisible to the human eye) image on a magnetic medium information of the protected product. Therefore, when revealing the key of the code used (which is possible with the modern development of the level of computer technology, since cryptographic protection, as a rule, is based on the logical relationship of the key with encoded information), the possibility of falsification of the protected product is not excluded.

 The basis of the invention was the task of creating such a means of protection against counterfeiting of products with an identifying contrasting image, which would provide almost absolutely reliable multilevel protection due to the statistically impossible repeated reproduction of the information carrier in an absolutely identical form, and also would enable the detection of this information medium by inexpensive and affordable for the general user means of detection.

 The solution of this problem is provided due to the fact that in the information carrier for protection against counterfeiting of products with an identifying contrast image containing a base having at least one section made of magnetic material with code information hidden from visual perception, which is formed as a group of security labels for reading the code through detection, and at least one security label from the group is made in the form of an image that is cryptographically adapted via the key to at least part of the identification contrast image of the product according to the invention, at least one security tag from the group is made of a material comprising a randomly generated mixture of at least two stable isotopes with different mass numbers and is functionally a means for determining which detecting this protective label of statistically random reference values of the mass ratios of isotope matter with different mass numbers.

 To optimize the conditions for detecting code information embedded in the information field of a patented information medium, it is advisable to perform at least one label from the group of security labels in the form of an image that is identical to at least part of the identification contrasting image of the product.

 The 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 invention, allowed to establish that the applicant did not find an analogue characterized by features identical to all the essential features of the invention, but selected from the list of identified analogues the prototype, as the closest analogue in the aggregate of essential features, made it possible to identify the aggregate of essential, in relation to technical result, the hallmarks of the claimed object set forth in the claims.

 Therefore, the invention meets the patentability criterion of NOVELTY under current law.

 To verify the conformity of the claimed subject matter of the invention with the patentability criterion, INVENTIVE LEVEL, the applicant conducted an additional search for known technical solutions in order to identify features that match the features of the invention that are distinct from the prototype, the results of which show that the invention does not explicitly follow from the prior art, as from the prior art determined by the applicant, the influence of the invention provided for by the essential features has not been identified Ia transformations to achieve a technical result sees the applicant.

In particular, the claimed object of the invention does not provide for the following transformations of the known prototype object:
the addition of a well-known object with any well-known attribute attached to it according to well-known rules, in order to achieve a technical result, in relation to which the influence of such an addition is established;
the replacement of any feature of a known object with another well-known feature to achieve a technical result, in respect of which the influence of such a replacement is established;
the exclusion of any feature of a known object, with the simultaneous exclusion due to the presence of a feature of this feature and the achievement of the usual result for such exclusion;
the increase in the number of similar signs 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;
creation of an object consisting of known features, the choice of which and the relationship between them are based on known rules and the technical result achieved in this case is determined only by the known properties of the features of this object and the relationships between them.

 Therefore, the invention meets the requirements of the patentability criterion of INVENTION according to the current legislation.

Thus, the above information indicates that when using the invention the following set of conditions:
- an object embodying the invention in its implementation is intended for use in industry, namely in the field of protection of valuable products from counterfeiting;
- for the claimed subject matter of the invention in the form described in the independent clause of the claims below, the possibility of its implementation using the means and methods described above or known from the prior art on the priority date has been confirmed;
- an object embodying the invention in its implementation is capable of achieving the achievement of the technical result perceived by the applicant.

 Therefore, the invention meets the requirements of the patentability criterion INDUSTRIAL APPLICABILITY under applicable law.

 The invention is illustrated by the drawing, which shows a General view of a patented information carrier in relation to its use in conjunction, for example, with an identification card of the company, which can be used to identify the products of the company.

 The product to be protected (identification card) contains a base 1 with contrasting identification images placed on it 2 (graphic representation of the company logo), 3 (graphic representation of the company name code), 4 (graphic representation of the code symbol of the protected product) and 5 (graphic representation of the product serial number ), as well as a section with code information hidden from visual perception, made in the form of a strip 6 of magnetic material. A group of security labels 7, 8, and 9 is formed on magnetic strip 6, which together with magnetic strip 6 (which can also be considered as an independent security label of the group) forms an information field of the information carrier. It is obvious that the basis 1 of the identification card in this example can simultaneously perform the function of the basis of the information carrier. One of the group’s security labels hidden from visual perception, for example, label 7, is formed in the form of an image that is cryptographically adapted by means of a corresponding key (for example, known only to the authorized manufacturer) to at least part of the identification contrast image of the product, for example, to image 5 of the serial product numbers. The mentioned adaptation of the label 7 to the image 5 of the serial number of the product (identification card) is advisable in view of the fact that this number is strictly individual for each specific product. Therefore, the code information generated on the information field of the considered tag 7 will also be strictly individual for each specific product (identification card). And this greatly increases the degree of protection against fake.

 To optimize the conditions for detecting code information embedded in the information field of a patented information medium, at least one label (for example, label 8) from the group of security labels is made in the form of an image that is identical to at least part of the identification contrast image (in this case, the image 5 serial number) of the product. This makes it possible to detect the tag 7 in conjunction (simultaneously) with the tag 8 by the same detection means, for example, a magnetic detector widely known in the art.

 The most effective (in the group of protective labels) in terms of protecting the product from unauthorized reproduction is a protective label (for example, label 9), which is made of a material that includes a statistically random mixture of at least two stable isotopes with different mass numbers. This protective label 9, in addition to its direct purpose, is also functionally a means for determining the reference, statistically random, values of the mass ratios of isotopic substances with different mass numbers used in the detection of this protective label.

 It is clear that this protective label can be implemented as an independent (independent of the other group labels) information field, or as part of the material of the magnetic strip 6, which is functionally an independent protective label in the group.

 The physical basis for the implementation of the protection of products from counterfeiting by means of the said label, which is made of a material including a statistically randomly generated mixture of at least two stable isotopes with different mass numbers, as well as methods for its detection are discussed in detail below.

In the process of developing a patentable means of protection against counterfeiting of valuable products, the following provisions were used (known from the prior art and / or empirically researched by the applicant) provisions:
firstly, the basic physical principle of creating and detecting spectrometric labels is based on the fact that when, for example, X-ray radiation with an energy E _{0 of an} isotope is excited of a given chemical element, a spectrum of characteristic radiation is emitted with a set of lines E (K _α ), E (K _β ) , E (L) characteristic of each of the mentioned elements. For modern hardware (radiation sources, radiation detectors), an apparatus has now been created for measuring the quantitative and qualitative composition of elements from fluorine (F) to uranium (U) with a relative percentage concentration of about 10 ^-4 % of the base material;
secondly, when a mixture of stable isotopes is introduced into any solution (for example, in printing ink or in a solvent specially used to form a protective isotope tag), the atoms of the isotopes that make up the mixture are distributed with a high degree of uniformity over the entire volume of the resulting composition. This is explained by the fact that the solvents used reduce the substances dissolved in them to the atomic level, therefore, the atoms of the isotopes used are part of the molecules of the resulting composition and are mixed. In this case, the maximum fluctuation of the particles of the dissolved substance per unit volume of the obtained composition is the square root of the total (average) number of particles of the substance in this volume. Usually in 1 cm ^{3 of} any substance the average number of particles is in the range of 10 ²¹ - 10 ²³ atoms (molecules). This means that the possible deviation (fluctuation) of the number of particles of the substance in the mentioned volume from this average range of values will be approximately 10 ¹¹ pieces (particles). That is, about 10 ^-9 percent is the non-uniformity of the concentration of particles of the substance in the solvent in spatially separated volumes of the obtained composition under normal stirring by methods known from the prior art using known means;
thirdly, as a result of the phenomenon described above, the statistical values of the ratios of the masses of isotope matter with different mass numbers in the formed protective label (as well as in any part thereof) remain constant, i.e., they are constants that can be used as reference values for detecting the authenticity of the verified valuable product;
fourthly, due to the fact that the accuracy of recording the quantitative content and, accordingly, the mass ratios of isotope substances in their mixture (or directly in the label formed on the basis of this mixture) significantly exceeds the accuracy of dosing of the ingredients of the mixture, which is statistically achieved during the preparation of the composition ( comprising a mixture of isotopes) to form a label, then the probability of repeated reproduction of the label composition with a microdose of a mixture of stable isotopes is identical (within the measurement error using X-ray enofluorestsentnogo detector) of the previously prepared composition of the mixture is less than 10-12%.

The above provisions allow us to conclude that the use of an isotope indicator (label) based on a mixture of stable isotopes (or their chemical compounds and multicomponent chemicals such as Cd ₂ O ₃ : Eu, Y ₂ as a means of protection against counterfeiting of valuable products O _3:. Eu, etc.) virtually eliminates the possibility of repeated reproduction composition tags with microdoses mixture of stable isotopes, identical (within experimental error by, for example, X-ray detector) of the previously prepared Songs of the mixture, which ensures high reliability and effectiveness of the protection at minimum cost at its (protection) implementation.

In the considered isotopic protective label, stable isotopes can be used, for example: deuterium ( ² H), carbon-13 ( ¹³ C), sulfur-34 ( ³⁴ S), chlorine-35 ( ³⁵ Cl), lead-204 ( ²⁰⁴ Pb), nitrogen-15 ( ¹⁵ N), oxygen-18 ( ¹⁸ O) and others.

As chemical compounds of stable isotopes to obtain the composition used to form the protective label, for example, the following compounds can be used: Cd ₂ O ₃ , Y ₂ O ₃ , as well as some multicomponent systems (chemicals) based on them (for example, Cd ₂ O ₃ : Eu, Y ₂ O ₃ : Eu, etc.), which under the influence of incident ultraviolet or laser radiation emit secondary optical radiation with a certain discrete wavelength.

 Stable isotopes can be obtained by enriching natural isotopic mixtures by repeatedly repeating the separation operation (distillation, diffusion, thermal diffusion, isotope exchange, electrolysis), as well as in mass spectrometric installations, in nuclear reactions and in electromagnetic separation plants known from the prior art and which are not objects of the present invention.

 The advantages of stable isotopes are their stability and the absence of nuclear reactions. In addition, stable isotopes can be easily detected and determined qualitatively and quantitatively by isotopic effects, in particular, by characteristic emission spectra, for example, the X-ray range, by means of methods and methods known from the state of the art. For example, by X-ray fluorescence analysis.

 To simplify the process of detecting a protective label and increase the accuracy of detection, it is advisable to use an isotope indicator based on stable isotopes of various chemical elements, the spectral regions of the characteristic x-ray radiation of atoms are located in different regions of the x-ray spectrum and are easily distinguishable by frequency characteristics.

 The use of stable isotopes in the patented information carrier as part of their chemical compounds in some cases allows to increase the bond strength of the isotopes with the carrier base or the base of the directly protected product, and also simplifies the process of applying (forming) a protective label.

 In accordance with the claimed technical solution, the protective mark is formed in such a way that it is possible to control its (protective mark) presence on the protected product (during detection) by at least one of the methods of spectral analysis, for example, X-ray fluorescence method.

 It is possible to create a multicomponent security label that can be identified both by the X-ray fluorescence spectral analysis method and by the luminescent method. It should be borne in mind that the sensitivity of measuring instruments for luminescent analysis is about four orders of magnitude higher than with the X-ray fluorescence measurement method.

 This security tag (together with a patented storage medium) can be formed directly on the basis of the protected product or independently of it in any form known from the prior art and using technologies known from the prior art, which is not the subject of the present invention, and therefore is not described in detail disclosed in the application materials.

 In particular, for the protection of banknotes and other securities, a patented information carrier with the considered group of security tags can be formed and applied to the protected product in the form of prepress, print or post-print security elements, the main list of names of which and the methods for their formation are given earlier.

 After the isotope protective label is formed on the information carrier, the statistical values of the mass ratios of the isotope substances with different mass numbers in said mixture are determined, for example, by X-ray fluorescence analysis of at least a portion of the formed protective label. X-ray spectral (X-ray fluorescence) analysis is carried out by exciting the X-ray spectrum of a mixture of stable isotopes with an X-ray pulse emitted by a miniature X-ray tube. The spectrum of the emitted radiation of the isotopes detected in the protective label of the mixture of isotopes is recorded by a silicon detector.

Such a recording device has dimensions not exceeding 10 x 8 x ³ cm ³ . Registration time does not exceed a few milliseconds.

 The values of the mentioned relations are stored as reference values for the detection of protected products during their subsequent checks (by the same method as the one described above), since the values of these relations for a particular isotope indicator (obtained as a one-time mixture of isotopes) are statistical constants (naturally , within the permissible error of measurement of an X-ray fluorescence detector, component 10-12%).

 It should also be noted that when using information in a patented medium as a means of protection against counterfeiting of an isotope tag (isotope indicator) based on a mixture of stable isotopes, it is necessary to take into account the operating conditions and the operating environment or handling of the protected products in order to use the preferred operating conditions and operating environment (treatment) the possibility of getting onto the protective label of isotopes formed according to the invention is identical to those used in the said isotope indicator.

 In addition, if it is necessary to authorized reproduction of valuable products, for example, banknotes according to the patented method, the manufacturer must either have a stock of the originally produced isotope indicator in the form of a mixture of stable isotopes or compositions based on them, or make a new one, naturally, different from the original one made according to quantitative composition, a mixture for the formation of protective marks on a reproducible batch of notes. In the second case, it is necessary to re-detect the second obtained mixture to determine (using the same method as in the first case) the additional reference values of the previously mentioned mass ratios of isotope substances with different mass numbers, and for subsequent authentication of all banknotes, use it for comparison both primary and secondary derived reference values of the ratios of the mentioned masses.

 Considering the fact that the isotope indicator (label) includes a mixture of stable isotopes with different mass numbers (as a rule, the mixture contains more than two isotopes of various chemicals), it is possible to significantly increase the reliability of product protection against counterfeiting by using an additional encoding labels (barcode), which carries information (known only to the legal manufacturer of the product) in relation to the spectra (or spectral sections) of isotopes of which particular chemical elements (included in the mixture) need to initiate in the detection products to verify their authenticity. In addition, the energy values in the radiation spectrum can serve as additional identifiers.

 It is possible to provide methods and means known from the prior art due to the widespread knowledge that the excitation energy and radiation intensity of different sections (or individual lines) of the radiation spectrum of atoms of various chemical elements (substances) are also different.

 In this case, the aforementioned information, laid down (by one of the well-known encoding methods) by the legal manufacturer in an additional code mark (barcode), is stored in the memory block of the electronic logic circuit of the detector used in authenticating the product.

 When detecting the product, information is read from the code label (barcode), which is processed by the electronic logic circuit of the detector. As a result of this processing, the detector comparison unit knows with which reference value (from the set of reference values stored in the memory block) it is necessary to compare the information received during the irradiation (exposure) of the protective label of the item under test.

 In this case, the radiation source of the detector is also programmed (by means of information received from the barcode) to a certain radiation energy, through which not all lines of the radiation spectrum of the used security label (which are thousands) will be excited, but only specific ones, the number and frequency of radiation of which is strictly regulated by the barcode.

 It is completely obvious that for different protected products or their batches, different code marks (barcodes) can be used, provided that the corresponding information for each code mark is stored in the memory block of the reference values of the detector electronic circuit used to verify the authenticity of the tested product. In other words, the detector used to verify the authenticity of products has a response to all the used code labels (barcodes), and the electronic logic circuit of this detector knows a specific answer to each specific code label (barcode).

 It is also obvious that decoding the information embedded in the code label (barcode) is possible only by opening the detector microcircuit. Therefore, it is advisable to perform the aforementioned chip self-destructive upon unauthorized introduction into it.

 The principles of the manufacture of self-destructive microcircuits are widely known from the prior art and are not disclosed in detail in the materials of this application, since they are not related to the subject of the patented invention.

 Thus, the invention can be widely used to protect products from unauthorized reproduction (fake), and its use is most suitable for industrial use mainly in large-scale production and authorized reproduction of protected products, such as banknotes and other securities, as well as various type of loan documents.

At the same time, a high degree of protection is guaranteed not through the use of any unique materials, methods and means of forming and detecting protective marks, but exclusively due to the extremely low probability (not more than 10 ^-12 %) of repeated reproduction of an isotope indicator in the form of a mixture of isotopes, which would be identical (within the measurement error provided by modern means of detecting stable isotopes) to the originally produced isotope indicator, even if it is repeated It is provided in the same manufacturer on the same production equipment.

Such a low probability (not more than 10 ^-12 %) of the reproduction of an identical (previously manufactured) isotope indicator, consisting of a mixture of stable isotopes, was confirmed by the method of statistical studies.

Therefore, given that the probability of re-creating an isotope indicator from a mixture of isotopes identical to that previously used on protected products is 10 ^-12 %, we can conclude that faking previously protected valuable products becomes economically impractical, since the cost of unauthorized production for example, banknotes will generally exceed the face value of these banknotes.

Claims (2)

 1. An information carrier for counterfeiting articles with an identifying contrasting image, comprising a base having at least one section made of magnetic material with code information hidden from visual perception, which is formed as a group of security tags, for reading the code through detection, moreover, at least one security label from the group is made in the form of an image that is cryptographically adapted by means of a key to at least part of the identification counter a solid image of the product, characterized in that at least one protective label from the group is made of material comprising a randomly generated mixture of at least two stable isotopes with different mass numbers, and is functionally a means for determining the reference used in the detection of this protective label, statistically random, values of the mass ratios of isotope matter with different mass numbers.  2. The storage medium according to claim 1, characterized in that at least one label from the group of security labels is made in the form of an image that is identical to at least part of the identification contrasting image of the product.