RU2638848C1 - Valuable document protected from forgery and method of determining its authenticity - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: valuable document contains an identification mark based on the elements made of an amorphous ferromagnetic alloy. The elements are segments of microwires connected to each other, having the ability to emit electromagnetic pulses with a jump-like magnetization reversal under the influence of an external sinusoidal magnetic field. The intensity of the exciting magnetic field is chosen to be from 0.1 to 1000 A/m, and the frequency of this field is in the range of 0.1 to 100 KHz. The pulses emitted at the field magnetization have the options characteristic for the protective label of number: the number of pulses, the ratio of their intensities and phases measured relative to the zero-phase referred to the magnetic field, with the formation of a given code.

EFFECT: invention provides a high degree of protection of documents and reliability of determining their authenticity.

12 cl, 4 ex, 2 dwg

Description

The invention relates to the field of protection of valuable documents from counterfeiting and is intended for instrumental determination of the authenticity of protected documents, such as banknotes and letterhead paper, labels, excise and postage stamps, payment, identification and travel documents, as well as groups of goods, access systems, plastic cards and other objects.

The essence of the invention consists in using magnetic elements based on amorphous-metal alloys with the property of magnetizing in a stepwise manner under the influence of an external magnetic field (the “Barkhausen effect”), and such magnetization reversal is accompanied by radiation into the space of an electromagnetic pulse, which allows reliable contactless, essentially remote, authenticated secure media. By changing the morphology (geometric dimensions) of the magnetic elements, their number in the label, as well as the properties of their material, it is possible to achieve a given combination of the ratio of intensities and phases of electromagnetic pulses emitted by the label in an external alternating field.

When creating the invention, it was found that if you rigidly connect two microwires made of amorphous metal alloys of different composition, differing in coercive force, that is, remagnetized at different magnitudes of the applied external magnetic field, you will get a device that when exposed to a sinusoidal magnetic field a given frequency will always give two pulses following at a given distance from each other in time, that is, have a strictly specified phase difference. In this case, the main factors determining the intensity of these pulses or the ratio of their intensities will be the composition of the material and the size of the elements (microwires) that form the label.

Thus, by varying the chemical composition of the alloy and the size of the microwires, it was possible to construct protective labels with desired properties, characterized by the ratio of intensities and phases of the emitted electromagnetic pulses following exposure to an external alternating magnetic field. Moreover, the set of phases and ratios of the intensities of the pulses can be considered as a “key” or “code” used to identify the medium containing the label.

A feature of the proposed technical solution, which allows expanding the number of varieties of unique security labels for various groups of documents and goods, is the use of a set of elements with different, but strictly specified magnetic properties as part of a single security label, forming a given identification code inherent in only one group of products. In this case, the security label, in essence, forms a coding unit, and the composition and content of the code is established during the manufacture of the security label and cannot be changed or destroyed.

Obviously, the present invention may be a coding system comprising a magnetic security identification tag and a method for determining the authenticity of this security tag.

In this case, a protective (identification) mark is a device, at least one of the elements of which is a magnetic element made of a ferromagnetic alloy having a certain geometric shape and a set of predetermined magnetic properties and serving as a hallmark or identifier.

The security label consists of one or more coding elements located on the surface of the substrate, directly on the surface of the object or embedded in the object. Elements consist of segments of microwires attached to each other or embedded in each other. The number of elements in the security label can be from 2 to n, depending on the required code. Depending on the required amount of information, several encoding units located in predetermined places can be placed in the security label. The number of states in the coding block is S = n-1. The amount of information in the coding unit is I = log ₂ n bits. The number of states in a security label containing N coding units is S = (n-1) ^N. The amount of information contained in the label containing N coding units is I = log ₂ (n-1) ^N bits.

To verify the authenticity of the document containing the proposed security tag, you can use the authentication method, which is implemented using a detector, which, in turn, consists of a sensor device, a signal amplification and processing device, a recognition and indication device (Fig. 1). In this case, the sensor device of the detector may consist of one or more coils creating an alternating magnetic field, and one or more sensors of the magnetic field receiving a signal emitted from segments of microwires.

The method for determining the authenticity of a document is as follows: under the influence of an external alternating magnetic field created by the exciting coils, the magnetic element of the label is magnetized and, at the time of magnetization reversal, emits a response electromagnetic pulse, which induces a voltage pulse in the sensor, is registered, processed and transmitted to the identification, memory and indication. Each coding element during magnetization reversal emits one pulse, and each coding block emits a burst of pulses, the number of which is equal to the number of coding elements in the block. Thus, the code reading algorithm consists in counting the number of pulses emitted by the coding unit. When using a security label containing several coding units, each unit emits a burst of pulses and is received from each unit by its own sensor.

The physical principle of the proposed technical solution is as follows: as you know, a single segment of a bistable microwire during magnetization reversal induces and emits a single electromagnetic pulse. When two or more segments of the same length are placed at a fairly close distance, magnetic interaction between the segments occurs. As a result of the interaction, the direction of the spontaneous magnetization of the segments becomes pairwise opposite. Such magnetization reduces the magnitude of the magnetic energy of the system of segments and is caused by the physical laws of magnetic phenomena of the “state with the lowest energy”. When an external magnetic field is applied to such a system, the effective effective field in close proximity to the system vectorizes from the external applied, external present (for example, the Earth's field) and induced by the system itself.

H _eff = H _vn + H _s + H _and

Thus, different segments of the microwire in the system find themselves in a different situation with respect to the applied external induced field, and the segment for which the total field becomes larger than the start field is the first to be magnetized. At the time of magnetization reversal, this segment induces an electromagnetic field pulse, and the induced pulse field from the segment of the microwire is directed opposite to the external induced by the magnetizing system. Thus, the magnetic situation near the microwire system changes, and the next segment is magnetized after the effective field reaches the value of the start field of this segment. After reaching the maximum value of the external magnetic field, all segments of the microwire block become magnetized in one direction. When the magnitude of the magnetizing field decreases at a time when the interaction field between the segments becomes larger than the external, the magnetization reversal occurs in the opposite direction. Moreover, a situation may arise in which the magnetization reversal of the segments occurs earlier than the external field decreases to zero. At the moment when the external field becomes equal to zero, part of the segments will already be magnetized. When the field increases in the opposite direction, the situation described above will arise. Thus, the number of pulses induced by a set of segments of microwires for half the period of change of the external magnetic field is equal to the number of segments in the system.

This ratio is observed on all systems of segments of bistable microwires, but the limiting number of segments in a block at which the system induces the number of pulses equal to the number of segments is different for different microwires. The authors experimentally established that there is an optimal ratio between the limit number of elements in the block, the properties of the microwire segments in the block, at which equality is fulfilled: the number of pulses is equal to the number of segments. In addition, the number of pulses equal to the number of segments of microwires in the block is observed only in a certain range of frequencies and amplitudes of the magnetizing field. If the rate of rise of the magnetization reversal field is above a certain limit value, then the probability of addition of pulses becomes large and the probability of an error in determining the correctness of the code increases. The rate of rise of the magnetizing field is the sum of the maximum amplitude and frequency. If the rate of rise of the magnetic field is too low, then the time required for identification and recognition increases, which leads to the restriction of the use of tags in rapidly changing conditions, and also increases the likelihood of error due to external electromagnetic interference. Therefore, there is an optimal value of the frequency and amplitude of the external magnetizing field.

A number of technical solutions are known that use a microwire as a magnetic element of tags in electronic systems for observing objects.

One such solution is described in WO 02082475. A microwire made of a cobalt-based alloy is proposed as a magnetic tag element, and a method for manufacturing it is described. The solution describes a microwire, which contains a core of a ferromagnetic alloy, consisting of cobalt (Co), iron (Fe), manganese (Mn), boron (B) and silicon (Si) selected in different percentages. It exhibits magneto-stable properties during magnetization reversal and is characterized by almost rectangular hysteresis loop. The microwire core is covered with a glass shell, the diameter of which is in the range from 5 to 35 microns.

The microwire is fabricated by heating the alloy located in the glass tube to a melting point, at which the material of the tube softens, the alloy overheats, followed by drawing the softened tube into the capillary tube and then cooling the capillary tube with the alloy. Next, the microwire is cut into segments that are used as magnetic elements of the labels. In the manufacturing process, depending on the applicable time and temperature conditions, an alloy having an amorphous, amorphous-crystalline, microcrystalline or fine crystalline microstructure can be obtained.

The disadvantage of this technical solution is that the coding blocks made of these microwires do not always induce the number of pulses equal to the number of coding elements in the block. As a result, the label code gives an erroneous code, and also, the response signal to the external magnetic field is not high enough, which makes it difficult to register the label.

Also known is the solution RU 2430433 C2, describing a method for manufacturing an amorphous alloy wire. The invention provides a method for manufacturing an amorphous magnetic alloy wire. The method includes placing a metal billet in a glass tube, melting the metal billet together with the tube, drawing the metal melt in the form of a metal wire coated with a glass layer, cooling to obtain an amorphous alloy wire coated with a glass layer, removing a glass layer from the wire surface. The removal of the glass layer is carried out by pulling the wire along the curved surface of the solid body across the generatrix of the curved surface with a radius of curvature, providing a tensile stress in the glass layer equal to or greater than its tensile strength and tensile stress in the wire during bending while stretching across the generatrix of the curved surface of the solid in the range of the tensile strength of the glass and the elastic limit of the amorphous alloy of the wire. The technical result is an increase in ductility, tensile strength, an increase in the degree of uniformity of magnetic properties along the length of an amorphous wire, as well as an increase in the degree of magnetization.

The present invention does not disclose the possibility of using microwires from amorphous metal alloys as sets of coding elements in the security label.

The prior art solution RU 2003101292 A is known that describes an identification mark that is made of an amorphous soft magnetic alloy containing copper, characterized in that the amorphous soft magnetic alloy is made of Co _a Ni _b Si _c B _d , where a + b + c + d = 100, where a = 20-85, b = 5-50, c = 2-13, d = 15-30, and the copper content in which is 1-3 wt.% With respect to the mass of the amorphous magnetically soft alloy, where a, b, c, d - weight percent.

The specified solution is not aimed at solving the problem of obtaining a valuable document with a security tag having a given set of properties that distinguishes it from a group of similar tags due to the use of sets of magnetic elements with specified magnetic properties forming an identification code as part of the security tag.

The prior art knows the solution RU 2005107892 A, describing a method for determining the authenticity of a security, including moving a security with magnetic active agents distributed in a security sheet with a given distribution function through an alternating magnetic field, registering electromagnetic radiation from each magnetic active authenticating agent, determining their quantity and assessment of the degree of authenticity of the security, characterized in that before assessing the degree of authenticity of the security, the security is interchanged. schayut through the light of a subsequent registration of the intensity distribution of the reflected light, and the assessment of the security authentication is made on-one correspondence of the intensity distribution of the reflected light, and magnetically authentication agent distribution function.

Obviously, in this case, the task of creating an identification mark inherent in a particular type of document is also not solved, since magnetoactive elements are randomly located, have the same magnetic and optical properties, and do not form an identification set of attributes inherent only to this group of documents (code).

The prior art solution RU 2007111536 A is known that describes a sheet material containing an authenticity agent made in the form of fibers of an amorphous magnetically soft material distributed in the mass of sheet material, the geometric and physical parameters of which are selected in accordance with predetermined values of the distribution function, characterized in that a sign is applied to the surface of the sheet material, one-to-one, corresponding to the value of the distribution function.

The task of creating an identification mark inherent in a particular type of documents has not been solved in this solution either, since magnetoactive elements, as in the previous source, are randomly located, have the same magnetic properties and cannot unambiguously characterize different groups of documents.

The solution RU 2009138455 A is also known, which describes a method for manufacturing an amorphous alloy wire, including placing a metal billet in a glass tube, melting a metal billet, drawing a metal melt in the form of a metal wire coated with a glass layer, cooling the wire alloy while maintaining the amorphous state of the wire alloy coated with a layer glass, removing a layer of glass from the surface of an amorphous alloy wire, characterized in that removing the glass layer from the surface of an amorphous wire th alloy operate pulling wire of amorphous alloy coated with a layer of glass, a curved solid surface across the generatrix of the curved surface.

This solution does not describe the process and method of forming a security label, including more than one coding element based on microwires with different magnetic properties.

A known solution RU 2219299 C1, describing sheet material for use in the manufacture of banknotes, securities, credit cards, as well as for the manufacture of labels for the goods or packaging of goods. The sheet material contains an authenticity agent made in the form of fibers of an amorphous magnetically soft material distributed in the mass of the sheet material. The length, width, thickness or diameter of the amorphous soft magnetic material or the values of its magnetic moments are selected in accordance with predefined values of the distribution function. The length of the fibers of the amorphous magnetically soft material is selected in the range of 0.5-32 mm. The fiber width is selected in the range of 30-400 microns. The fiber thickness is selected in the range of 0.3-30 microns. The diameter of the fibers is selected in the range of 3-400 microns. Fibers are distributed uniformly in the mass of sheet material with a density of 20-20 × 10 ³ g / t. The fibers are made of a soft magnetic magnetostrictive alloy. The fibers are made of amorphous soft magnetic material of the systems Fe-Co-Ni, Fe-Ni-B, Co-Mn-Si-B. The invention also describes a method for determining the authenticity of sheet material, which includes moving the sheet material with an authenticity agent through a magnetic field, recording the amplitude of the response of the signal from each of the fibers from an amorphous magnetically soft material, and evaluating the degree of authenticity of the sheet material. When evaluating the degree of authenticity of the sheet material, the distribution function of the amplitudes of the response of the signals is determined, and the authenticity of the sheet material is estimated by the shape of the curve of the integral and / or differential distribution function of the amplitudes of the response signals. EFFECT: reduction of the possibility of falsification and facilitation of the proof of authenticity, as well as cost reduction in the production of sheet material.

The closest in technical essence to the claimed invention - analogues are the magnetic element and the method of its manufacture described in US patent 6441737.

The magnetic element of the patented identification tag is made in the form of at least one piece of microwire with practically zero magnetostriction, having a ferromagnetic alloy core coated with a glass shell. This microwire is made of cobalt-based alloy with different percentages of Co, Fe, Mn, B, and Si, which leads to its various microstructure.

According to the invention, a method of manufacturing a magnetic element is carried out by casting a microwire from a melt having a ferromagnetic alloy core coated with a glass shell, and cutting the microwire into pieces.

Labels are formed from the obtained segments of the microwire, using one segment or several segments connected in different ways.

The main disadvantage of patented technical solutions, like the analogue described above, is that the coding blocks made of these microwires do not always induce the number of pulses equal to the number of coding elements in the block and the insufficiently high level of the response signal of the magnetic element obtained by the described method, on the influence of an external magnetic field, which limits the detection zone of the label, complicates its registration and increases the likelihood of error.

In addition, the segments of the microwire described in the analogue and prototype have a large fluctuation of the magnetizing field, which limits the possibility of using a large number of elements in the label block.

As a result, the previously proposed solutions do not allow the creation of a security label with a code formed by elements based on microwires from an amorphous metal alloy, with given amplitudes and signal repetition phases when exposed to an external alternating magnetic field.

To expand the detection zone and increase the reliability of reading labels made up of coding blocks, it is necessary that the voltage pulses induced in the reading coils of the detector be as large as possible in amplitude, and when using several elements, the number of pulses must be equal to the number of coding elements in the block .

In the proposed technical solution, in order to increase the amount of information contained in the security tag, increase the reliability of its identification, increase the detection distance, the security tag is made in the form of one or more coding units formed by sets of elements in the form of microwires from an amorphous metal alloy. The coding block consists of coding elements, for example, segments of microwires tightly interconnected and bundled or connected coaxially. The number of coding elements in the coding block can be from 1 to n, depending on the specified code.

To increase the reliability of counting the number of pulses induced from the elements of the security label, the device for determining the authenticity of the security label can include a magnetization system that induces an alternating magnetic field of a given frequency and amplitude, and the increase in the magnetic field can have a sinusoidal linear or step law. Such an increase law allows creating conditions under which a magnetic situation arises at the location of the coding element, which ensures the detection of all pulses induced by the coding unit. Also, to increase reliability, the authentication device may include a system of magnetic field sensors arranged so that each sensor reads a signal from a specific coding unit.

Separately, it is worth dwelling on the advantages and possible ways of solving the problem of controlling the properties of a valuable document containing a security label based on a set of segments of a microwire made of an amorphous metal alloy.

As a rule, modern valuable documents already contain security elements made using magnetic inks, security threads, etc. Obviously, accidentally located protective labels based on segments of the microwire will create strong interference for magnetic scanners and will not allow you to measure and / or analyze the magnetic properties of the document.

To solve this problem, it is advisable to apply modern technological methods and introduce protective labels into the material of the carrier of a valuable document locally or in a strip (the so-called strip method of introduction). With this approach, it is possible to provide the ability to measure the specified magnetic properties of a valuable document located in one part of it, and to determine the authenticity of the security mark located in its other part, or in a dedicated area.

The objective of the proposed invention is to increase the level of security, providing the possibility of expert or machine authentication, with the possibility of multiple authentication of the product, allowing for reliable contactless (remote) authentication.

The problem is solved through the use of a security tag as a part of a valuable document, including two or more elements made of an amorphous metal alloy with a shell, characterized in that the elements are sections of a microwire with different geometric dimensions and / or chemical composition that emit electromagnetic pulses during a jump-like magnetization reversal under the action of an external magnetic field with a strength of 0.1 to 1000 A / m, characterized in that the emitted pulses have a given e and unique to this label number and mutual relationship of the intensities and phases characterized specify the ratio of the measured relative to the exciting magnetic field, which together can reliably identify the authenticity and type of the value document. The protective label is characterized by the fact that its constituent elements are made in the form of sections of a microwire based on an alloy, the magnetic properties of which change significantly during plastic deformation, for example, an iron-cobalt-based alloy having the composition (Co Fe) Cr B Si.

The security tag is also characterized in that the size of its elements is from 0.1 mm to 100 mm.

To increase the degree of security of the document, the invention is characterized in that the protective mark is introduced into the paper or polymer mass, or into the surface layer of paper or polymer, or applied as an adhesive layer between the inner layers of the multilayer carrier.

A valuable document can be made in the form of a banknote, an excise stamp, a postage stamp, a passport, a travel document, a driver’s license, identity card, security, plastic card, label, payment document.

The problem is also solved due to the fact that the elements of the protective label are connected in the form of a beam, or in the form of a flat structure, or in the form of a coaxial structure, or form any combination of the above.

The invention is also characterized in that the security tag elements can form a code intended for automatic reading by the detector.

The invention can be characterized by the fact that the security tags can be arranged randomly and uniformly in the entire volume of the document carrier, or evenly arranged in the form of a strip with a width of 1 to 100 mm, and can be absent in other parts of the document carrier.

The invention also describes a method for determining the authenticity of a valuable document, characterized in that the label is exposed to an alternating magnetic field of a strength of 0.01 to 1000 A / m, the electromagnetic pulses emitted from the elements of the protective label are fixed with a sensor in the form of a receiving coil, which must have given and characteristic only for this label the quantity, intensity and phase, measured with respect to the phase and intensity of the exciting magnetic field, compare the obtained values with their reference values and on the basis of AANII comparisons conclude the document's authenticity.

The proposed invention is illustrated by examples and illustrations.

Example 1

A valuable document in the form of an excise stamp contains protective labels in the paper carrier, each of which is two glued sections of a microwire 5 mm long, one of which has a core diameter of 10 μm, and the second 50 μm, made on the basis of an iron-cobalt alloy containing components , wt.%: (Co 49.5; Fe 50.0); Cr 0.2 V 0.1; Si 0.2.

In both microwires, the metal core has a shell of low-melting glass with the following components, wt.%: Bi ₂ O ₃ 42,0; PbO 38.0; ZnO 12.0; SiO ₂ 2.0; B ₂ O ₃ 6.0.

These protective marks are uniformly and randomly placed over the entire surface of the excise stamp and are not visible to the naked eye when observing the reflection under diffuse lighting.

The device shown schematically in FIG. 1, where:

1 - tag code;

2 - LF generator;

3 - magnetizing coils;

4 - magnetic circuit;

5 - read coil;

6 - low-pass filter;

7 - amplifier;

8 - identification and indication device.

When the brand is exposed to a sinusoidal magnetic field with a frequency of 10 KHz and a voltage of 1 A / m, both sections of the microwire (element) are magnetically magnetized and emit two pulses that follow each other with a mutual phase difference exceeding π / 20 and with a common phase difference measured relative to the zero phase of the external sinusoidal magnetic field, exceeding π / 10, and mutually differ in intensity by about 5 times.

This ratio of the intensity and the phases of the two pulses is inherent only for this mark, they are instrumentally measured with high accuracy, as a result, the brand is established.

These measurements were carried out repeatedly and showed high accuracy of the proposed method.

Example 2

A valuable document in the form of a passport contains protective labels in the paper of the cover page, each of which represents three glued sections of the microwire (“element”) connected by an adhesive layer in the form of a flat structure 10 mm long, one of which has a core diameter of 7 μm, the second is 21 microns, the third is 49 microns. The first element is made on the basis of an iron-nickel alloy with a content of components, wt.%: (Fe 40.0; Ni 40.0); S 14.0; At 6.0. The second and third elements are made on the basis of an amorphous alloy with a content of components, wt.% Fe 70,0; Cr 10.0; P 15.0; In 5.0.

In all three elements, the amorphous-metal core has a shell of low-melting glass with the content of components, wt.%: Bi ₂ O ₃ 42,0; PbO 38.0; ZnO 12.0; SiO ₂ 8.0.

These protective labels are evenly and randomly placed on the entire surface of the cover page of the passport.

To verify the authenticity of the passport, the device schematically shown in FIG. one.

When a sinusoidal magnetic field with a frequency of 100 KHz and a voltage of 1000 A / m is exposed to the cover page of the passport, all three elements included in the label are magnetically remagnetized and emit three pulses that follow each other with a mutual phase difference exceeding π / 20 , and with a total phase difference measured relative to the zero phase of the external sinusoidal magnetic field exceeding π / 10, and are mutually different in intensity with a ratio of about 1: 3: 7.

This ratio of the intensity and the phases of the two pulses is inherent only for this mark, they are instrumentally measured with high accuracy, as a result, the authenticity of the passport is established.

Example 3

A valuable document in the form of a banknote contains protective labels in the paper carrier, each of which is three glued sections of the microwire (“element”) connected in the form of a bundle 7 mm long, one of which has a core diameter of 5 μm, the second - 20 μm, the third is 50 microns. The first element is made on the basis of an amorphous alloy containing components, wt. % Fe _80.0 P _13.0 V _7.0 . The second and third elements are made on the basis of an amorphous alloy containing components, wt. %: Fe 70.0; Cr 10.0; P 15.0; At 5.0.

In all three elements, the amorphous-metal core has a shell of low-melting glass with the content of components, wt.%: Bi ₂ O ₃ 42,0; PbO 38.0; ZnO 12.0; SiO ₂ 2.0; B ₂ O ₃ 6.0.

These security tags are randomly placed in a 30 mm wide strip located across the long side of the banknote, as shown in FIG. 2. The presence of protective marks in a given zone and a given size (length) of the zone allows the denomination of a banknote to be identified and also indicates its authenticity. To verify the authenticity of the banknote, the device schematically shown in FIG. one.

When a banknote is exposed to a sinusoidal magnetic field with a frequency of 10 KHz and a voltage of 100 A / m, all three sections of the microwire (element) are magnetically magnetized and emit three pulses that follow each other with a mutual phase difference exceeding π / 20 and with a common the phase difference, measured relative to the zero phase of the external sinusoidal magnetic field, greater than π / 10, and mutually differ in intensity with a ratio of about 1: 4: 10.

This ratio of the intensity and the phases of the two pulses is inherent only for this mark, they are instrumentally measured with high accuracy, as a result, the authenticity of the banknote.

Example 4

A method for determining the authenticity of a valuable document in the form of a passport containing protective marks in the paper of the cover page, each of which is three glued sections of a microwire (“element”) 10 mm long, one of which has a core diameter of 7 microns, the second - 21 microns the third is 49 microns. The first element is made on the basis of an iron-nickel alloy with a content of components, wt.% (Fe40,0; Ni 40,0); S 14.0; At 6.0. The second and third elements are made on the basis of an amorphous alloy with a content of components, wt.% Fe 70,0; Cr 10.0; P 15.0; At 5.0.

In all three elements, the amorphous metal core has a shell of low-melting glass with the content of components, wt.%: Bi ₂ O ₃ 42,0; PbO 38.0; ZnO 12.0; SiO ₂ 8.0. These protective labels are evenly and randomly placed on the entire surface of the cover page of the passport.

To verify the authenticity of this passport, the authentication method implemented in the device schematically shown in FIG. one.

The method consists in the fact that on the cover page of the passport with the help of a generator and inductance coils they are exposed to an alternating magnetic field with a voltage of 100 A / m and a frequency of 1 KHz, then the pulses emitted by the tag are recorded by a sensor made in the form of a receiving coil, it is determined -decision device, the number of pulses, the ratio of the intensities of the pulses and the phases following, measured relative to the phase of the exciting magnetic field, compare the obtained values with their reference (given) values values, which for a genuine passport should be 3 pulses with an intensity ratio of approximately 1: 3: 7, and a phase difference of at least π / 20, and based on the comparison, they conclude that the document is authentic.

Claims (12)

1. Valuable document containing an identification tag based on elements made of an amorphous ferromagnetic alloy, which are segments of microwires connected to each other, capable of emitting electromagnetic pulses during spasmodic magnetization reversal when exposed to an external sinusoidal magnetic field with a strength of 0.1 to 1000 A / m and a frequency from 0.1 to 100 KHz, while the emitted pulses have the following parameters characteristic of only this protective mark: the number of pulses, respectively Ocean their intensities and the phase measured relative to the zero phase of said magnetic field to form a predetermined code. 2. A valuable document according to claim 1, characterized in that the intensity and frequency of the external magnetic field is selected based on the condition that the number of emitted pulses when exposed to a magnetic field is equal to the number of segments of the microwire in the label. 3. The document according to claim 1, characterized in that the identification tag is made in the form of coding units formed by a set of microwires connected in the form of a bundle, or a flat structure, or a coaxial structure, or a combination thereof. 4. The document according to claim 1, characterized in that the identification mark is entered into the document locally or in the form of a strip. 5. The document according to claim 1, characterized in that the coding unit generated when a magnetic field is applied to the document provides the possibility of its automatic reading by the detector. 6. The document according to claim 1, characterized in that it consists of a banknote, an excise stamp, a postage stamp, a passport, a travel document, a driver’s license, an identity card, a security paper, a plastic card, a label, a payment document, and an identification tag is entered in paper or polymer pulp or in the surface layer of paper or polymer, or applied as an adhesive layer between the inner layers of the multilayer carrier. 7. The document according to claim 1, characterized in that the size of the label elements is from 0.1 to 100 mm. 8. The document according to claim 1, characterized in that the identification mark is made indistinguishable when observing for reflection in the visible range under diffuse lighting. 9. The document according to claim 1, characterized in that the identification tag contains a microwire made of an alloy whose magnetic properties change significantly with plastic deformation. 10. The document according to claim 1, characterized in that the security label elements are made of an iron-cobalt alloy (Co Fe) containing chromium (Cr), boron (B) and silicon (Si), or an iron-nickel alloy (Fe Ni) containing composed of phosphorus (P), boron (B) and sulfur (S). 11. The document according to p. 10, characterized in that the elements of the protective label are covered with a shell of fusible glass. 12. The method for determining the authenticity of a valuable document, described in paragraph 1, characterized in that the identification mark of the document is affected by an alternating magnetic field of a strength of 0.01 to 1000 A / m and a frequency of 0.1 to 100 KHz, fixed by a sensor made in the form of a receiving coil, the parameters of electromagnetic pulses radiated from the label elements determine the number of pulses, the ratio of the intensities of the pulses and the repetition phases measured relative to the phase of the exciting magnetic field, compare the field chennye from their reference values (predetermined) values on the basis of this comparison conclude authenticity of the document.

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