RU2069626C1 - Monetary or warranty document of rectangular shape - Google Patents

Abstract

FIELD: banknotes and warranty documents. SUBSTANCE: invention may be used for manufacture of identification cards. It is intended for increased protection of documents with graphic representation. First protective symbol of document is made in the form of periodic grid of parallel lines of water marks arranged with inclination relative to edge of document. It is superimposed on second protective symbol manufactured in the form of stripes of printed graphic representation parallel to edge of document. Water marks are represented by at least two colors. Reaction of dye-stuffs of different pairs of stripes symmetric relative to center of second edge of document to electromagnetic radiation of specified invisible range of waves (for instance, infrared) specified in advance is different for at least one of dye-stuffs which provides for binary coding of mentioned stripes. EFFECT: increased protection of documents. 14 cl, 21 dwg

Description

 The invention relates to monetary or guarantee documents relating to the type of documents containing a printed graphic image and safety signs, moreover, these documents may constitute, in particular, bank tickets.

 Documents of this type are known, the safety signs of which are made by using a magnetic wire, completely or alternating hidden in the paper shell of this document, moreover, this wire can be encoded; these documents are of interest because they are well adapted to automated controls designed to detect the presence of magnetic wire in a passing document and to decode this wire to identify the specified document.

 Such a technology actually has limitations regarding the effectiveness of determining the authenticity of documents, which encourages resorting to complex types of coding.

 There are also documents whose safety signs are based on the principle of changing the density of fibers (bulk or surface mass), with special coding.

 Periodic dry embossing was proposed along a strip parallel to the edge of the document, and the indicated embossing provided in the manufacture of paper allows thus to change the bulk density along the specified strip, with the flattening of this strip when printing a document.

 As an option, a sequence of steps of stamping and counter-stamping of the forming web is used, which makes it possible to obtain a sequence of dark and light zones on a document in accordance with a specific type of watermark such as a mesh with watermarks, and this mesh may be periodic or non-periodic.

 This technology, however, is limited, since in most cases it is compulsory with respect to orientation (large or small edges parallel to the direction of passage), from the face of the document (front-back) of the document and from the direction of its transmission (right-left ) in the machine for processing.

 There is also a method of encoding a document with sequences of strokes, of which some absorb and others reflect infrared radiation, in order to determine the authenticity of these documents.

 In general, the listed safety signs were used singly or in combination with each other, and in the latter case, it was required to use different types of sensors for sequential recognition of these characters.

 Currently, there is a need to improve this authentication technology in order to counter the increasingly sophisticated technology used in document forgery.

 In the particular case of bank tickets, the additional problem of automatically recognizing its indicated value should also be solved.

 A specialist in this field, however, encounters great difficulties trying to combine various signs of protection, on the one hand, because the analysis technology is quickly complicated and requires the use of various sensors, often bulky and poorly compatible with each other, and on the other hand, because that the decisions made often depend on the face of the front and on the orientation of the document.

 In addition, the machines used for sorting, counting and / or distribution are improved in order to increase their productivity.

 This explains the fact that specialists are generally forced to use security signs of the same type, depending on the goal (in particular, in the case of authenticity recognition or determination of the indicated value of bank tickets).

 The subject of the invention is the production of a monetary or guarantee document, the security signs of which provide at the same time the best assistance in determining the authenticity and easy recognition.

 The subject of the invention is also the creation of a document whose security signs are designed in such a way as to abstract from the face of the front side and from the orientation of the specified document, as well as from its spatial location with respect to the transmission direction.

 The subject of the invention is also the creation of a document whose security signs would be as invisible as possible when inspected with unarmed gas so as not to attract attention.

 And, finally, the subject of the invention is the production of a document, which could be analyzed by means of analysis with digital processing methods, which are both simple and very reliable.

 The problem is solved in that a money or guarantee document of a rectangular shape with a printed graphic invention and security signs is proposed, containing according to the invention two security signs superimposed on each other, made in the form of a grid, of which the first security sign is represented in the form of a grid of periodic watermarks , and the second security sign is the result of dividing the printed graphic image into parallel stripes located and encoded in binary code, symmetrically with respect to july to the axis of symmetry of this document, while the wave front of the wave-like relief of this watermark grid extends in a general direction that is practically not perpendicular to the direction of the indicated separation bands of the printed graphic image, and the superposition of these two protection marks on each other, thus, affects reading specified characters individually.

 Preferably, the watermark grid forming the first security mark contains waves with a sinusoidal profile of the surfaces of the mass. This really excludes the presence of sharp contrasts at the level of the edges of the wave (in fact, a wave of square or rectangular shape would be sharper and less invisible). In particular, changes in the amplitude of the waves of the grid of watermarks are carried out around the middle plane of the specified document, which allows you to get rid of the requirements for reversal of the front side of the document.

It is also advisable that the wave of the grid of watermarks passed almost in the general direction, making an angle of 45 ^o with respect to the direction of the separation bands of the printed graphic image. Thus, it is possible to read a document, regardless of the face of the face, from the orientation of the specified document, from the spatial position relative to the transmission direction.

 According to another expedient distinguishing feature, the watermarked grid defines a surface whose closed contour is located inside the edges of the specified document, the specified surface being completely intersected by the separation bands of the printed graphic image.

 In this case, it is preferable that the grid of watermarks be made in the form of a square, and the dimensions of this square are preferably selected relatively large to maintain good flatness of the document (this problem is especially acute if bundles or bales containing a large number of documents are used), and to enhance the stealth of this sign of protection. It is also advisable that the edges of the square are beveled, as a result, the phenomenon associated with the introduction at the level of the edges, which is the result of increased contrast, is prevented, as a result of which the invisibility of this sign of protection against this is further improved.

где Т обозначает длину волны сетки из водяных знаков. Идентичность значений ширины полос разделения и симметрия их расположения позволяет облегчить анализ документа, подразумевая несколько возможных видов кодирования, это особенно выгодно в случае, когда данный документ представляет собой банковский билет, при этом кодирование позволяет в данном случае производить распознавание указанного достоинства.According to a particular embodiment, the separation bands of the printed graphic image have the same predetermined width e, which is a function of the angle β between the general direction of wave propagation of the watermarked grid and the direction of the separation bands when the specified angle b exceeds the reference angle corresponding to the strip width reaching half the width of the specified document, in particular, the width e of the separation bands is given by the formula:

where T denotes the wavelength of the watermark grid. The identity of the values of the width of the separation bands and the symmetry of their location makes it easier to analyze the document, implying several possible types of coding, this is especially beneficial in the case when this document is a bank ticket, while coding allows in this case to recognize the indicated value.

 Alternatively, the separation strips of the printed graphic image have the same width, depending only on the desired encoding, and not on the angle b between the general direction of propagation of the watermarked grid wave and the direction of the separation strips, when the specified angle b is less than the reference angle corresponding to the strip width, reaching half the width of the specified document. This is true for the case with the propagation direction parallel to the direction of the separation bands, however, the analysis technique in this case should be appropriate.

 It is also advisable that the graphic drawing of this document was printed using two inks of the same color, of which one responds and the other does not respond to a predetermined electromagnetic radiation of the invisible wavelength range in order to determine the separation of this graphic image into parallel stripes.

 This electromagnetic radiation can be of various types (infrared radiation, microwave radiation, ultraviolet radiation, magnetic pigments or a radioactive source).

 In particular, the graphic image is also printed using other inks that do not respond to the specified predetermined electromagnetic (e.g. infrared) radiation, the same is true for the graphic invention provided on the back of the specified document.

 In the case of a document containing a graphic image printed on its both surfaces, it is advantageous that the separation bands of this graphic image can be encoded on the front side or on the reverse side, or on the front side and on the reverse side of the specified document.

 In particular, a graphic image of the specified document is printed using a pair of inks, one of which reflects infrared radiation, and the other does not.

 And finally, if this document is a bank ticket, it is advisable that the first and second signs of its protection serve to determine the authenticity of the ticket, and the second sign of protection also serves for mechanized recognition of the indicated value of the ticket.

In FIG. 1 shows a rectangular document according to the invention, the first and second security signs of which are shown in dotted lines, these signs superimposed on each other;
in FIG. 2 is a plan view illustrating the first security mark of the indicated document, which is made in the form of a periodic grid of watermarks, formed in this case in the form of a square, as it can be seen in the light, with alternating light in this area with watermarks;
in FIG. 3 in plan, the front embossed surface of the matrix, which allows stamping the forming web in the manufacture of the document, to obtain a periodic grid of watermarks, similar to that given in FIG. 2, while the waviness of this embossed surface, in this case sinusoidal, allows you to make the required changes the surface mass in this watermarked area, the edges of this matrix are also beveled in this case to mitigate contrasts at the level of the edges of the specified area;
in Fig. 4, 8 sections, respectively, according to IV IV, VV, VI VI, VII - VII and VIII VIII in Fig. 3, allowing a better understanding of the structure of the relief surface of the matrix, and, in particular, its beveled edges, in relation to the middle plane of the specified surface;
9 to 13, curves illustrating changes in the surface weight of the watermarked zone obtained with the indicated matrix, and these curves correspond to cuts respectively in FIG. 4 8 (curves of changes in surface mass in paper are actually direct transforms of the corresponding curves of changes in the relief of the surface of the matrix for stamping);
FIG. 14 and 15 are an illustration of the document of FIG. 1 with two different types of coding of parallel strips of the second grid, in the form that this document accepts, for example, when viewed under infrared radiation (for a printed graphic using two inks, one of which reflects infrared light, while the other does not), in this case, in eight parallel stripes, respectively encoded 1 011 1101 and 0 110 0110;
in Fig.16 view of the lumen of the periodic grid of watermarks obtained above the matrix with a square contour with beveled edges and with a special phase displacement with respect to the axes of the square (which preferably coincide with both symmetry axes of a rectangular document);
in FIG. 17 is a view of a larger scale showing a document zone in which both security signs are superimposed on one another (in this case, there are six parallel stripes of the second grid that intersect the watermarked zone with the first periodic grid), and from this figure it can be seen that both grids are superimposed on one another in such a way as to ensure analysis of the document using a single element at the level of which the document is skipped;
FIG. 18 supplements the previous view, depicting a bar with sensors, one sensor for each parallel strip of the second grid, said bar being perpendicular to the transmission direction of the document;
in FIG. 19 is a variant of the image in which the propagation direction (DC) of the watermarked wave of the grid with watermarks is not inclined, as before, at an angle of 45 ^o to the direction of passage (DD), but parallel to the specified direction of passage, moreover, the bar with detectors in this case is made differently, with two offset rows of sensors, as can be seen in this figure;
in FIG. 20 fragments illustrating various arrangements of the sensors of the bar of FIG. 13, respectively having openings in the form of inclined slots, cross-shaped holes, multiple sensors with two adjacent sensors and multiple sensors with four sensors arranged in a square shape;
on Fig a diagram of an analysis device associated with a strip of sensors according to Fig. 13, which shows the means used to process signals from various sensors in order, on the one hand, to verify the coding of the second grid and to determine the authenticity of the analyzed document when the second grid meets the established requirements, and, on the other hand, to analyze first grid and confirm the authenticity of the analyzed document when the first grid meets the established requirements.

 Figure 1 shows the document 1, in this case a rectangular shape, the large side of which is indicated by the number 2, and the small number 3.

 This document contains on one side (front or back) a printed graphic image G, illustrating in this case a hang glider. A graphic image, of course, can be provided on the other side of the document 1.

 According to the invention, document 1 comprises two superimposed security marks 100, 200, shown here in dashed lines.

 The first security mark 100 is represented in the form of a periodic grid with watermarks, limited by a closed circuit C, which is located inside the edges 2, 3 of document 1. This first security mark is therefore visible in the light and in this case contains a sequence of dark and light stripes 101, 102. The appearance of these bands 101, 102 is the result of changes in surface mass in this watermarked area.

 The second security mark 200 is also in the form of a grid, but this second character is the result of representing the printed graphic image G in parallel stripes 201, 202, which are encoded.

 The bands 201, 202 are located symmetrically with respect to the axis of symmetry of document 1, in this case in the form of an axis X 'X, which is parallel to the large edge 2 of the specified document. Therefore, there is an even number of pairs of strips located on both sides of the X ′ X axis. The other axis of the document is designated Y ′ Y in FIG.

 The direction of the bands 201, 202 is indicated by DD and it can be seen that this direction coincides with the direction of passage of the document.

 Since it is not necessary that the bands 201, 202 relate to the entire document 1, so, in FIG. 1, two zones are distinguished that are not covered by ZL coding. In the case of, in particular, a bank ticket, these two ZL zones can be used for numbering.

 These stripes 201, 202, in addition, are encoded in binary code (0 or 1), symmetrically with respect to the axis of symmetry X 'X of document 1. The encoding of the bands 201, 202 is thus implemented along the axis Y' Y.

 In this case, it is advisable that the graphic image G of the document be printed using two inks of the same color, one of which responds to a predetermined excitation, and the other does not, in order to present the specified graphic image in the form of parallel stripes.

 Although various types of excitation can be used (magnetic pigments, microwaves, UV radiation, radioactive source), it is advisable to choose infrared radiation. In this case, the infrared wavelength should be chosen in such a way as to obtain the best pair result formed by both security signs 100, 200, so that the response waveforms considered during the analysis of the document coincide at least partially.

 It is preferable to choose a wavelength slightly less than one micrometer, and in particular between 0.8 and 1 micrometer (therefore, we are talking about the lower infrared region, which is significantly removed from the thermal infrared region, sometimes used for document analysis, in the case of wavelengths of at least 3 microns).

 In the case when the graphic image of the documents is printed using two inks, one of which reflects infrared radiation, and the second does not reflect, consideration of this document in infrared radiation corresponds to images similar to those shown in Figs. 14 and 15.

 In FIG. 15, a band 202 encoded by one can be sequentially seen (absorbs infrared light, therefore, it allows one to see the considered part of the graphic image, as well as the considered part of the first watermark grid 100), the band 201 encoded by zero (reflects infrared light, therefore, masks graphic image, thus allowing to see only the area of the first grid of watermarks 100), then two bands 202 encoded by unit. The symmetry of the coding with respect to the X ′ X axis in this case entails the presence of two bands 202, strip 201 and finally one strip 202 in series.

 Thus, the binary encoding shown in Fig. 14 will be expressed by the number 10111101.

 On Fig shows another encoding with the same number of parallel bands in this case, the encoding will be expressed by the number 01100110 (the symmetry of the encoding with respect to the axis X 'X is fully respected).

14 and 15, eight parallel strips are provided, as a result of which 2 ⁴ , that is, 16 different codes, are actually arranged.

More generally, with 2n bands encoded 0 or 1, there are 2 ⁿ distinct codes.

 Coding by splitting a printed graphic image may refer to a front surface, a reverse surface, or both of them. In the latter case, the reading of the document will be facilitated if the same coding is used on the front side and on the back side, and the corresponding bands are directly superimposed on one another, this feature may turn out to be beneficial to the extent that it allows better resistance to aging.

 In practice, a number of bands is selected that is at least equal to the number of documents to be recognized (for example, in the case of bank tickets, when the second character is used to automatically recognize the indicated value of the analyzed ticket), while the number of bands remains, in addition, limited by the technological capabilities of the analysis tools working on very thin stripes.

 In addition, a graphic image can be printed (on the front and / or back) using other inks that do not respond to excitation corresponding to coding in the form of parallel stripes (for example, infrared radiation).

 This feature can be used for banknotes for offset printing, in particular gravure printing, which makes it easy to stack inks thanks to engraved rollers (there is no problem of registering with inks, since the same printing plate is used in this case).

 Figure 2 allows you to better distinguish the zone with watermarks corresponding to the first sign of protection 100, as it is visible in the light.

 The watermarked grid 100, therefore, is periodic (uniform alternation of opaque and bright zones), with a period T. In addition, as will be explained in detail below, this watermarked grid contains waves, (i.e., has a wavy relief) which preferably have a sinusoidal surface layer profile.

 Figure 2 also shows that the wave of the watermarked grid 100 passes in the general direction DC, which is substantially not perpendicular to the direction DD of the separation bands of the second grid 200.

In this case, the indicated directions ДС and DD form an angle b between themselves, which is 45 ^{o here} , which allows reading the document in two perpendicular directions (parallel to the long edge, which is usually used in machines for processing, in particular, bank notes, or parallel to the short edge).

 Alternatively, you can choose other values for the angle b between both of these directions, however, with the loss of certain advantages. On Fig shows a special case where the directions of the DC and DD are almost parallel, and in this case, implies a special arrangement of the detector sensors, as will be described later with reference to this figure.

 It should also be noted that in the embodiment shown in FIG. 2, there is a certain phase shift for the waves of the first grid 100 with respect to the center of the square located at the intersection of the axes X 'X and Y' Y of the document. The choice of such a phase shift in which the edge of the strip is brought to the level of the center O of the square will depend on the version of the analysis used and on the appropriate processing means. As a result, a sensor located at a certain distance from the X 'X axes at Y' Y always receives the same signal (with a deviation of p or 2π).

 The structure depicted in figure 1, in any case, remains the most acceptable, since the implementation of both superimposed on one another nets, namely a periodic grid with watermarks 100 and encoded grid 200 in the form of parallel separation bands of the printed graphic image, allows in the General case independently read the document (not depending on the face of the document on its orientation and on the direction of its passage).

Figure 3 shows the front embossed surface of the matrix 110, which allows stamping the forming fabric in the manufacture of the document, to obtain a periodic grid of watermarks, similar to the grid in figure 2. This embossed surface has a wavy shape, in this case sinusoidal, and extends in the general direction of DC, at an angle of 45 ^o .

 The embossed surface of the matrix 110 thus has a sequence of depressions 111 and protrusions 112 (better seen in cross section in FIG. 4), which allow alternately light 102 and dark 101 zones to be executed on a grid of watermarks 100 of the document.

 Curve IV in Fig. 9, showing changes in surface mass in the watermarked area of the document (according to the direction DС), in this case, corresponds to changes in the topography of the matrix 110 shown in Fig. 4.

 It is important to note that the changes in the amplitude of the sine waves of the watermarked grid shown in Fig. 9 occur around the middle plane of the document, designated PM (which allows reading independence with respect to the face of the document).

 The period T should preferably be chosen large in relation to the size of the document, for example, of the order of 10 mm for a bank ticket, so that the security sign 100 is as invisible as possible. The same applies to the side of the square, which should be, for example, of the order of 60 mm.

 Sections of figures 5-8 allow, in addition, it is better to distinguish the specific skewness of the edges 113 of the matrix 110. This skewness is practically formed in this case either downward (edges 113 'with chamfered) or upward (edges 113' 'with chamfered) with respect to the average planes of the embossed surface of the matrix 110.

 This is expressed by “chamfered” edges for the watermarked area, as follows from curves V VIII, illustrating the corresponding changes in surface mass, all of which take place on both sides of the mid-plane of the PM of the document. The result is a square in the form of watermarks, the edges of which are made in the form of "lace", which eliminates sharp contrasting transitions around the zone with watermarks and further improves the invisibility of the protection mark.

 Fig. 16 shows (by light) a periodic grid of watermarks 100 obtained from a forming web previously stamped with the indicated matrix 110, in particular, the beveled edges 103 of the square should be noted. As for the opaque 101 and bright areas 102, they correspond to what was previously described with reference to figure 2.

 On Fig shows a larger scale area of the document 1, on which the security signs 100 and 200 are superimposed on one another.

 Alternating dark and light zones in the form of stripes 101 and 102 of the periodic grid in the form of watermarks 100 have the same width, which is equal to the half-period T / 2 of the sine wave of the specified grid.

The slope of these bands 101 and 102 is indicated by the angle b between the directions DC and DD (angle b denotes here 45 ^o ).

 17 also makes it possible to distinguish coded parallel stripes 201, 202 of the second security mark 200 corresponding to the separation of the printed graphic image.

 The coded stripes have the same width e, which in most cases depends on the parameters of the watermarked grid, more precisely, on the period T and angle b.

В конкретном случае b 45^o, следовательно,

,
что соответствует, например, ширине полос в 10 мм (с шестью полосами), для периода в 14,14 мм.In FIG. 17 shows a right triangle ABC corresponding to the most appropriate structure for reading a document in which the hypotenuse AB corresponds to the width e of each of the bands 201 or 202, and one leg of which corresponds to the half-period T / 2 in this case, therefore, there is a relation:

In a particular case, b 45 ^o , therefore,

,
which corresponds, for example, to a strip width of 10 mm (with six stripes), for a period of 14.14 mm.

The above ratio, however, can only be used within certain limits, that is, as long as the angle β exceeds the reference angle b _o corresponding to a strip width e ₀ reaching half the width of the document 1, this extreme case would practically correspond to the presence of two stripes symmetrical with respect to the x 'x axis.

For example, in the case of a bank ticket with a width of about 80 mm, the reference angle β _o would be about 10 ^o .

When the angle β becomes smaller than the reference angle b _o , the width e of the separation bands 201, 202 of the printed graphic image is selected mainly depending on the required encoding.

 The specific case of the zero angle is shown in Fig. 19 of the strip 101, 102 of the first stack 100 in this case, orthogonal to the strip 201, 202 of the second grid 200, and in this case, you can choose the width e, which is preferably equal to the half-period T / 2 (in this In this case, the image would correspond to the correct ruler of the square with six orthogonal stripes).

In practice, it is first necessary to choose the number of separation bands depending on the number of documents to be encoded and on the manufacturing technology that allows these encoded bands to be performed, as well as on the symmetry stresses. This choice will also depend on the accuracy of the reader used to analyze the document. The possible angles β must then be determined, taking into account that an angle of 45 ^° provides maximum benefits, as explained above.

 Thus, a document containing two security signs superimposed on each other, 100, 200 of the above type is of interest to the extent that the overlapping of these two characters affects the reading of these characters individually.

 Thus, it is possible to substantiate to a large extent the effectiveness of determining authenticity.

 In the case where the document is a bank ticket, the first security sign 100 and the second security sign 200 are used to determine the authenticity of the ticket, and the second security sign 200 is used to automatically recognize the indicated value of the ticket.

 The indicated version of the analysis method and the device associated with it are described below with reference to Fig. 18 21.

 In fact, FIG. 18 shows a document area 1 on which both security signs 100 and 200 are superimposed on one another (as for FIG. 17) with an additional image of a reading bar 301 provided with detection means.

 The detection means in this case are made in the form of sensors 300 of at least one sensor per encoded strip 201 or 202 of the second grid 200 (in this case, one per strip). These means are located in the main direction D, perpendicular to the direction DD, which represents the direction of the document in the reader (the direction DD is also the direction of the encoded bands 201, 202) and with an intermediate distance d equal to the width e of the specified encoded bands 201 or 202.

 In addition, it is advisable that the detection means 300 are located on the middle axis (a) of the combined strips 201 or 202 of the second grid 200, thus avoiding any risk of distortion of the analysis in the case of a displacement of the document with respect to the sensors of the reading bar (signal loss from due to increased interference).

 We can talk about a single reading bar, the sensors of which contain transmitting and receiving means, and under which the analyzed document passes. Alternatively, two reading strips are applied one on top of the other, one of which contains transmitting means and the other receiving means, between which the analyzed document passes. In this case, in FIG. 13 schematically shows either this single bar, or one of two bars superimposed on one another (the other is below it).

 Fig. 18 also makes it possible to understand that in the case where the sensor 300 associated with the encoded strip 201 or 202 reads the minimum surface mass (the sensor is located in the center of the inclined strip 102, on the axis of the specified strip), the sensor 300 associated with the symmetric strip 201 or 202 (conjugate strip), reads the maximum surface mass (sensor in the center of the inclined strip 101, on the axis of the specified strip), this follows from the fact that the structure of the watermarked grid with a sinusoidal wave profile is chosen so that the waves on both sides of axis X 'X document located on one and the same distance from said axis, are in antiphase.

 In a more general raw material, at any time, a relationship is found between the response signal of the encoded strip 201 and 202 and the response signal of the symmetric encoded strip (conjugate strip) when this document passes under the reading bar 301.

This allows you to formulate a distinctive part of the document analysis method, according to which:
detecting means 300 are provided in an amount of at least one per strip 201, 202 of the second wall 200, and these means are installed in the main direction D, perpendicular to the direction of passage DD, with the same intermediate distance d equal to the width e of the parallel strips 201, 202 of the second grids
check the coding of the second grid 200, summing the response signal from each band encoded by zero or one unit and from the band symmetrical to it in order to eliminate the influence of the first grid 100, and comparing the results with theoretical encoding values,
analyze the first grid 100 by subtracting the response signals of each band that does not contain the encoding of the encoded 0 or symmetrical band.

 According to this method, by summing the response signal from each encoded strip and the response signal of the adjacent strip, it is possible to simultaneously remove the signal from the first watermarked grid and improve the response signal in infrared radiation, it is preferable to use decoding by synchronous integration for each pairs of encoded bands (in this case, this pair is formed by a coded strip and symmetric with it or a conjugate strip), then by mutual comparison of the obtained results with theoretical coding values.

 Subtracting the response signals from pairs of bands that do not have coding (encoded 0), in particular, the absorption levels of infrared radiation, we can analyze the first watermarked grid the easier the better the signal-to-noise ratio of this grid (in practice, the signal has a double amplitude by contrasting the phase of the grid with the watermarks between the paired encoded strips of the same channel).

 In the case of FIG. 19, for which the directions DC and DD are almost parallel (both superimposed grids form in this case a lined grid of the zone with watermarks), it is necessary to change the reading bar 301.

Instead of a single row of sensors 300 located perpendicular to the direction of passage of the DD, in this case, the reading strip 301 contains two parallel rows of sensors 300 ', 300''located perpendicular to the direction of passage of the DD, with one row on half of the strip these two rows of sensors (in this case each contains three sensors 300 'or 300'') in this case, offset from each other by a predetermined distance d ₁ , which is preferably almost equal to half the wavelength T / 2 of the first grid, in order to detect leaving the previous phase between the response sensors.

 Sensors 300 'or 300' 'of the same row are furthermore located on the middle axis (a) of the connected encoded strips 201, 202 of the second grid and are located at the same distance d, practically equal to the width e of said encoded strips.

This allows us to thus formulate a distinctive feature of this variant of the analysis method, according to which:
detecting means 300 ', 300''are arranged in an amount of at least one per strip 201, 202 of the second grid 200, and these means are located in the main direction D, perpendicular to the direction of passage of DD, and are located on the middle axis a of adjacent bands 201, 202 wherein, on one side of the indicated axis X'X of the document 1, the first detection means 300 'are disposed along one line, and on the other side of the indicated axis X'X, the second detection means 300''are also located on the same line, but displaced in relation to the first Wed dstvam detection 300 'by a distance substantially equal to half the wavelength of T / 2 of the first grid 100,
check the coding of the second grid 200, summing the response signal from each band encoded by zero or one and its symmetrical band conjugate with it, in order to exclude the influence of the first grid 100, and comparing the results with theoretical values of coding,
analyze the first grid 100 by subtracting response signals from each band that does not contain coding encoded with zero, and from a band symmetrical with it.

 In this case, the same analysis process is actually used with the addition of the response signals of the conjugated encoded bands and with the subtraction of the absorption levels of the pairs of bands for one or more channels used for coding (bands encoded with zero).

 Such an analysis process, therefore, is very advantageous, since it allows a double analysis of these superimposed protection signs using a single strip with sensors, and this despite the fact that the superimposition of these two signs on each other affects the readings separately each of them.

 This analysis process will be described in more detail below, with reference to Fig.21, which schematically illustrates a single device for analyzing signals from various sensors, in order to, on the one hand, verify the encoding of the second grid and determine the authenticity of the analyzed document, when the readable grid meets the necessary requirements, and, on the other hand, analyze the first grid and determine the authenticity of the analyzed document, when the readable grid also meets the necessary requirements.

 Naturally, there are numerous ways of making the reading bar, as follows from the examples described below.

 The reading strip 301 may have substantially circular holes 302 spaced at the same distance, connected to each sensor, as shown in FIG.

 Alternatively, openings in the form of slots 303 can be provided (Fig. 20, a) in which case each slit is tilted so as to be practically perpendicular to the direction of propagation of the wave of the first grid (as a result, each slit is tilted at the same angle b in relation to the transmission direction DD).

 According to another embodiment, there are provided cruciform openings 304 (FIG. 20, b), both branches of which are respectively parallel and perpendicular to the direction of passage of the wave of the first mesh. This allows you to further increase the integration surface for the first grid and get a higher average value for the measured signal, since in this case the integration discretization process is used.

According to another embodiment shown in FIGS. 20, c and 20, d, at least one of the sensors is combined (in this case, all six sensors are combined). 20, with each combined sensor 300 formed by two adjacent identical sensors 300 ₁ located on both sides of the middle axis (a) of each encoded strip 201 and 202. The response from the sensor 300 in this case will be the sum of the response signals from both sensors 300 ₁ . In FIG. 20, d, each combined sensor 300 is formed by four identical sensors 300 ₂ arranged in a square, this square centered on the middle axis (a) of each encoded strip 201 or 202, and the edges of the square are parallel and perpendicular to the direction of passage of DD.

 Obviously, the variants of FIGS. 20, a d may be applicable to the case with a bar with two offset rows, illustrated in FIG. 19, in this case with two offset rows of slots, inclined or crosswise, or with two offset rows of combined sensors.

 In the general case, the sensors 300 or 300 ′, 300 ″ of the reading strip 301 should preferably be configured to have the same gain and the same initial setting so as to balance the different channels.

 The single or combined sensors may be photodiodes or phototransistors or else photoresistors, each of these sensors preferably being connected to optical filters to fully match the desired wavelength.

 The following describes a complete device for the analysis of signals from various sensors of the read bar, with reference to Fig.21.

 21 shows a reading bar 301, in this case with six sensors 300 for a document with six coded strips parallel to the direction of travel, with the corresponding signal denoted SA, SB, SC being removed from three sensors, and the signal SA being removed from three other sensors ', SB', SC 'corresponding to the coded coded bands.

 The analysis device comprises means 400 for processing signals from sensors 300.

 These processing tools contain two blocks, each of which is associated with a grid of 100 or 200 documents.

 Using the first block, the coding of the second grid of the document passing at the level of the bar with sensors is checked and the authenticity of the analyzed document is determined when this grid meets the necessary requirements.

 The specified first block contains primarily summation means 401 associated with each pair of coded bands. As a result, the received signals correspond to the signals SA + SA ', SB + SB', and SC + SC '(these sums consist of the signal and the same signal shifted by p), previously amplified by the amplifiers 412 introduced. The signals are fed further to integrating means 402, integrating along the entire length of the analyzed document.

 As a result, signals 1A, 1B, 1C are obtained related to each pair of encoded bands. These signals are supplied to the comparator 430 to compare the obtained results with the theoretical encoding values of the second grid of the analyzed document.

 Preferably, switching means 408, 409 are provided upstream and downstream with respect to the integrating means, and these switching means (schematically shown here as switches) are respectively controlled by the passage of the leading edge and trailing edge of the document in front of a stationary element, such as a photodiode (in of the quality of the variant, at least one of the sensors of the reading strip can itself provide an additional function for controlling the passage of the ticket, which prevents the need for a separate photodiode a), in this case, the control of means 408, 409 is schematically shown as a central control unit 415.

 Thanks to this fixed detection element (built-in or stand-alone photodiode), in this case integration over the entire length of the document is ensured. This is especially advantageous for bank tickets of the same width and length.

 Comparison tools 403 make it possible first of all to verify that each value 1A, 1B, 1C is really within a given range, the boundaries of which are determined depending on the colors, paper tonality and other parameters related to the document in question.

Comparison tools 403 are provided with an audible contrast signal 410 that is triggered when the difference between the results is outside the specified plug. In this case, all the differences I _i I _{j are} compared with the limits of the range, and the audible alarm 410 is turned on if there is no paint that responds to a known excitation (for example, infrared radiation), or if the paint does not respond properly to this excitation.

сравниваются с границами диапазона. Этот вариант предпочтителен как с точки зрения достижения симметрии результатов, когда ответные сигналы инвертируются, получения высокой чувствительности в диапазоне малых отклонений контраста, так и возможности получения оптимальной реакции на черное и минимальной на белое.Alternatively, the contrast sound 410 is turned on when the relationship between the results is outside the specified range. Means comparing 403 in this case contain logarithmic relationship amplifiers and a range comparator (positive or negative). In this case, all values

are compared with the borders of the range. This option is preferable both from the point of view of achieving symmetry of the results when the response signals are inverted, of obtaining high sensitivity in the range of small deviations of contrast, and the possibility of obtaining the optimal response to black and minimal to white.

Preferably, the first block comprises decoding means 411 after the means of comparison 403 in order to identify the document, and in particular when the document is a bank ticket, in order to recognize the indicated ticket value. These decoding tools 411 have in memory inequalities I _i <I _j for each document, which makes it easy to identify the analyzed document.

,

и

при выполнении при этом еще предпочтительно предварительного усиления с помощью встроенных усилителей 413. Каждое различие соответствует, из-за противоположности фазы для сетки с водяными знаками двухкратному исходному сигналу, освобожденному от помех, вызванных загрязнениями документа и прозрачности бумаги.The second block contains primarily the means of differentiation 404 associated with each puncture of the encoded bands. The received signals thus correspond to the signals

,

and

while still preferably pre-amplifying using built-in amplifiers 413. Each difference corresponds, due to the opposite phase for the watermarked grid, to a two-fold source signal, freed from interference caused by document dirt and paper transparency.

 Selector means 405 are also provided, downstream of each of the differentiation means 404, to store only response signals related to bands lacking coding (zero-coded). These means are schematically depicted in this case by switches controlled by the central unit 415, while the switch associated with the bands SC and SC '(zero encoded) is closed here.

 It is advantageous to apply the received signals to additional addition means 412 (since the signals coincide in phase, they actually receive n times the signal, where n = 1, 2 or 3).

 Next, filtering means 406 are introduced, which allow filtering of signals with the fundamental frequency of the first grid, which makes it possible to select a useful signal. The latter is supplied to the recognition and authentication means 407 in order to analyze the first grid of the document and to recognize the document as authentic when the watermark grids meet the specified requirements, or otherwise, turn on the existing sound alarm 414. These means 407 may include an aperture comparator and / or means for threshold detection of nonlinear distortion, or else detecting the number of periods.

 It goes without saying that it is possible to group in one single functional block the means of amplification 413, summation 401 and integration 402 of the first block, and means of amplification 413 and differentiation 404 of the second block.

 The described method and apparatus of analysis greatly facilitate the determination of authenticity.

 In the case of a fake document, encoding of parallel stripes may not be observed (second grid), but in this case the decoding circuit does not recognize the authenticity of the document, and in addition, reading the grid with watermarks on the channel in question will not be possible due to paint that is sensitive to infrared radiation. This can also result from falsification of a periodic grid of watermarks (first grid), but in this case, if the amplitude is too large, the detection is facilitated; if the phase is not observed, the signal emerging from the channel difference will be very attenuated in this case, and if the profile is not sinusoidal, the measurement of non-linear distortion allows detection.

 The invention is not limited to the above-described embodiments, but, on the contrary, includes all variants that repeat, using equivalent means, the main distinguishing features set forth above.

Claims (14)

 1. Rectangular money or guarantee document with a printed graphic image on at least one side of the document and with two security signs, the first security sign is made in the form of a grid of parallel lines, characterized in that the first security sign is superimposed on the second security sign made in stripes of a printed graphic image parallel to the first edge of the document, represented by at least two different inks, moreover, the reaction of paints of different pairs of said stripes symmetrical about the middle in the second edge of the document, the electromagnetic radiation of a predetermined invisible wavelength range is different for at least one of the colors, which ensures binary coding of the said strips, while the grid of parallel lines of the first sign of protection is made in the form of a periodic grid of parallel lines of watermarks located tilted to the edge of the document.  2. The document according to claim 1, characterized in that the watermark grid forming the first security mark contains waves with a sinusoidal profile of the surface mass.  3. The document according to claim 2, characterized in that the changes in the amplitude of the waves of the watermark grid are carried out relative to the middle plane of the said document. 4. A document according to any one of paragraphs. 1 to 3, characterized in that the parallel lines of the periodic grid of watermarks are oriented at an angle of 45 ^o to one of the edges of the document.  5. A document according to any one of paragraphs. 1 to 4, characterized in that the watermark grid forms a surface, the closed contour of which is located inside the edges of the said document, while the said surface is completely intersected by the separation stripes of the printed graphic image.  6. The document according to p. 5, characterized in that the watermark grid is made in the form of a square.  7. The document according to claim 6, characterized in that the edges of the square are made beveled. 8. A document according to any one of paragraphs. 1 to 7, characterized in that the stripes of the printed graphic image have the same predetermined width e, which depends on the angle β between the perpendicular to the parallel lines of the watermark grid and the direction of the separation bands of the printed graphic image when the angle b exceeds the reference angle corresponding to bandwidth e _o equal to half the width of the document. 9. The document according to p. 8, characterized in that the width e of the stripes of the printed graphic image is given by the formula

where T is the watermark grid wavelength. 10. A document according to any one of claims 1 to 7, characterized in that the stripes of the printed graphic image have the same width, depending only on the required encoding, and not on the angle b between the perpendicular to the parallel watermark grid lines and the direction of propagation of the printed stripes graphic image, when the angle b is less than the reference angle corresponding to the strip width e _o equal to half the width of the document.  11. A document according to any one of claims 1 to 10, characterized in that one of the aforementioned colors absorbs electromagnetic radiation of a predetermined invisible range of wavelengths, and the other paint reflects this radiation.  12. The document according to p. 11, characterized in that the electromagnetic radiation of a predetermined invisible range of wavelengths is infrared radiation.  13. The document according to claim 11, characterized in that the decomposition of the printed graphic image into coded parallel stripes is made from at least one of the sides of the document.  14. A document according to any one of claims 1 to 13, characterized in that when the document is a bank ticket, its printed graphic image includes the dignity of the bank ticket, and the decomposition of its printed graphic image into coded parallel stripes allows machine recognition indicated dignity.

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