FR2977051A1 - Method for manufacturing authentication labels and associating signature to labels affixed to e.g. vine bottle, involves storing information representative of positions of characteristic elements of holograms/diffracting elements - Google Patents

Abstract

The method involves forming a set of holograms or diffracting elements on labels (110), and capturing an image of the set of holograms or diffracting elements (160) carried by each label. A position of a characteristic element e.g. surface's center of gravity, of the set of holograms or diffracting elements carried by the label is determined (165). Information representative of the respective positions of the characteristic elements of the holograms or diffracting elements is stored (170), where each hologram or diffracting element is in the form of disk. An independent claim is also included for a device for manufacturing authentication labels and associating a signature to each of the labels affixed to products.

Description

The present invention relates to a label for authenticating a product, a method for manufacturing this label and a method for authenticating a product to which this product relates. tag is associated. Labels intended to identify products, for example those carrying a bar code, make it possible to identify a type of product but not to authenticate it, that is to say to verify that it is not a question of of a copy, especially because these labels are easy to duplicate. The present invention aims to remedy these disadvantages. For this purpose, according to a first aspect, the present invention is directed to a method for manufacturing authentication tags and to associating a signature with each of said tags, which comprises: a step of forming at least one hologram or diffracting element on each said tag and - for each tag: - a step of capturing an image of a plurality of holograms or diffracting elements carried by said tag, - a step of determining the position of an element characteristic of a plurality of holograms or diffracting elements carried by said label and - a step of storing information representative of the respective positions of the characteristic elements of the holograms or diffracting elements. Thanks to these provisions, it is possible to determine and memorize a signature of the label, a signature formed by respective offsets of holograms or diffracting elements formed on said label.

According to particular characteristics, the characteristic element of each hologram or diffracting element is the center of gravity of its surface. Thanks to these arrangements, the characteristic element is weakly sensitive to label deterioration or image capture problems. According to particular features, the characteristic element of each hologram or diffracting element is the center, each said hologram or diffracting element forming a disk.

Thanks to these arrangements, the characteristic element is very weakly sensitive to label deterioration or image capture problems since missing disc elements can be reconstituted. According to particular features, each said hologram or diffracting element is formed separately from at least one other hologram or diffracting element. Thanks to these provisions, the respective positions of the characteristic elements of the holograms or the diffracting elements are subject to a hazard related to the positioning tolerances of the formations of holograms or diffracting elements. According to a second aspect, the present invention aims at a device for manufacturing authentication tags and for associating a signature with each of said tags, characterized in that it comprises: a means for forming at least a hologram or diffracting element on each said label, - a means of capturing an image of a plurality of holograms or diffracting elements carried by each said label, - a position determination means of a characteristic element d a plurality of holograms or diffracting elements carried by said label and - a means for storing information representative of the respective positions of the characteristic elements of the holograms or diffracting elements.

Since the advantages, aims and particular characteristics of this device are similar to those of the method that is the subject of the present invention, they are not recalled here. Other advantages, aims and particular features of the present invention will emerge from the description which follows, for an explanatory and non-limiting purpose, with reference to the appended drawings, in which: FIG. 1 represents a first label formed in accordance with the method FIGS. 2 to 4 show other labels formed in accordance with the manufacturing method that is the subject of the present invention. FIGS. 5 and 6 represent, in the form of a logic diagram, steps implemented in one embodiment of the invention. particular embodiment of the method of manufacturing labels object of the present invention and Figure 7 shows, in logic diagram form, steps implemented in a particular embodiment of the authentication method of a label object of this invention.

FIG. 1 shows a label 10 which is the subject of the invention and bears, on its side not intended to be contiguous to a product (not shown) to be authenticated, a zone 15 for the visual identification of a product, a sequence 20 alphanumeric symbols readable by the naked eye, an anti-copying mark visible to the naked eye 25, a micro-writing of alphanumeric characters 30, a zone of hologram or bare diffracting elements 35, an anti-copying mark, invisible copy to the naked eye 40, a two-dimensional bar code 45, an information source indication 55 on the product and geometric patterns 50.

The product to be authenticated is of any type. In the embodiment represented in FIG. 1, the visual identification of the product present in zone 15 represents a "Cru Bourgeois", that is to say a bottle of wine, a year representing a vintage, here 2009 and a capacity, here 750 ml. These indications are printed. The label 10 is adapted to be stuck on the container or the packaging of the product so that its takeoff without chemical causes visible deterioration of the label 10. The entire label 10 carries holograms or diffracting elements 35, here circular, partially covered by the marks 15, 20, 25, 30, 40, 45, 50 and 55. In particular, a white background 60, masking the holograms or the diffracting elements, is interposed between these holograms or the diffracting elements and the printed marks 20, 25, 40, 45, 50 and 55. The sequence 20 of alphanumeric symbols represents, by coding, on the one hand, variable information from one label to another, preferably unique for each label and an identifier of the manufacturing tool of the label 10. The skilled person can implement different types of generators of different numbers and different types of reversible encodings in To obtain this sequence of symbols 20. These types of generators and codings are therefore not detailed here. The anti-copy mark visible to the naked eye 25 is a mark comprising details which are degraded in the event of a copy and whose degradation is measurable. For example, the measurement of the degradation is performed by comparing the image of the anti-copy mark with an image of the original mark. In another example, the anti-copy mark 25 represents a sequence of symbols provided with an error correction code ("CRC") and the count of the number of error correction to be made gives a measurement, or score, which, in comparison with a limit value, indicates whether the anti-copy mark is an original mark or a copy.

Alphanumeric character micro-writing 30 represents a readable message with an optical instrument. The degradation of the micro-writing allows, with this optical instrument, to evaluate in the eye whether the label is an original label or a copy. In embodiments, the symbol sequence 20 is reproduced, possibly duplicated, in the micro-writing 30.

Holograms or bare diffracting elements 35 preferably represent the same geometrical shape, here disks. A characteristic point of this geometric shape, here its center, represents, with the identical points of other holograms or diffracting elements 35, a dispersion of almost aligned points. The successive offsets of the characteristic points with respect to a straight line, respectively vertical or horizontal, provide a signature for identifying the label 10 or a batch of labels 10.

The anti-copy mark invisible to the naked eye 40 is a dispersion of weakly contrasting points with the background, each point being separated from the other points of this dispersion. Preferentially: the points centers are offset from each other by a value which is not a multiple of the dimensions of these points but a multiple of a fraction of the dimensions of these points, the values of the differences of the vertical and horizontal dimensions of these points are not a multiple of the smallest of these dimensions but a multiple of a fraction of this smaller dimension and / or the values of the differences between the vertical and / or horizontal dimensions of these points are not a multiple the minimum dimension of these points, respectively vertical or horizontal but a multiple of a fraction of the minimum dimension. Fractions considered here are 1/2, 1/3, 1/4 or 1/5. Preferably, the multiples of these fractions are uniformly present in the mark 40.

The two-dimensional bar code 45 carries generic or unit identification information of the product. For example, the barcode 45 is a Data Matrix. The information source indication 55 allows a user or consumer of the product to learn about this product. In the embodiment shown, the indication 55 is an electronic address of a page of a web site (www.crus-bougeois.com). FIGS. 2 to 4 show labels 11 to 13 which are the subject of the invention and respectively bear, on their faces not intended to be contiguous to a product (not shown) to be authenticated, a zone 16 to 18 of visual identification. of a product, a sequence 21 to 23 of alphanumeric symbols readable by the naked eye, an anti-copy mark visible to the naked eye 26 to 28, a micro-writing of alphanumeric characters 31 to 33, an area of hologram or bare diffracting elements 36 to 38, an invisible anti-copy mark to the naked eye 41 to 43, a two-dimensional barcode 46 to 48, an indication of a source of information 55 on the product, and geometric patterns 51 to 53. The geometric patterns 50 consist of points distributed along geometric lines. The position of the geometric patterns is variable between different labels 10 to 14. For this purpose, during the manufacture of the labels, it is preferentially implemented cutting cylinders and printing having different numbers of poses. For example, with 114 poses on the cutting cylinder and 144 poses on the printing cylinder, a number of different positions is generated equal to the smallest common multiple of these numbers, ie about 2700 different positions. Preferably, the contents of the sequence of alphanumeric symbols readable by the naked eye, the anti-copy mark visible to the naked eye 25, the anti-copy mark invisible to the naked eye 40 and the bar code. in two dimensions 45 are synchronized, that is to say are representative of at least one common information. It can be seen in FIGS. 1 to 4 that each of these protection elements varies. Thus, the generation of a false sequence, a false anti-copy mark and / or a false bar code is detectable by simple search (reading and decoding) of this common information. As seen in FIG. 5, in a particular embodiment of the method for manufacturing labels that is the subject of the present invention, during a step 105, a print medium is produced during a step 115, an information printing step is carried out on said support and, during a step 150, information representative of the label is stored. The label 10 is adapted to be adhered to the container or the packaging of the product so that its takeoff without chemical causes visible deterioration of the label 10. For this purpose, the print medium takes, initially , the form of a glued plastic tape whose glue is protected by a film adapted to be easily separated from the glue. Alternatively, the gluing and the protection of the glue are made after manufacture of a label strip, before cutting. Step 105 includes a step 110 of forming at least one hologram on each said label. Preferably, each hologram or diffractive element is formed separately from at least one other hologram or diffracting element and, more preferably, from a plurality of other holograms or diffracting element, see all other holograms or diffracting elements. Step 115 comprises, a step 120, during which the determination is made for different groups of labels of different positions.

Preferably, during the step 120 of determination of positions, at least two manufacturing cylinders whose circumference represents two different numbers of labels are used, one of said cylinders being adapted to cut labels and another of said cylinders being adapted to form said sets of points. The entire label 10 then carries the holograms or diffracting elements 35 partially covered by the marks 15, 20, 25, 30, 40, 45, 50 and 55. In particular, a white background 60, masking the holograms or the diffracting elements, is interposed between these holograms or the diffracting elements and the printed marks 20, 25, 40, 45, 50 and 55 before the step 125. Then, for each of the different groups of labels, one carries out: - a step 125 of printing a background to be printed, here a white background and - a step 130 of forming a set of points 50 arranged on interlaced lines, said lines having positions depending on the position determined during the position determination step. The geometric patterns 50 consist of points distributed along geometric lines. The position of the geometric patterns is variable between different labels.

Preferably, cutting and printing cylinders are used with different numbers of poses. For example, with 114 poses on the cutting cylinder and 130 poses on the printing cylinder, a number of different positions is generated equal to the smallest common multiple of these numbers, ie 7410 different positions. During a step 135, at least one identifier of at least one label manufacturing tool is determined. During a step 140, a unique value is determined for the label and, by coding this unique value and the identifier of at least one manufacturing tool, the values of the sequence 20, of the mark 25. , characters 30, the mark 40 and the two-dimensional bar code 45. In particular, the sequence 20 of alphanumeric symbols thus represents, by coding, on the one hand, variable information from one label to another, preferentially unique for each tag and an identifier of the manufacturing tool of the tag 10. The values of the other identification elements, 25, 30, 40 and 45 may not depend on the manufacturing tool identifier. In the course of a step 145, for each label object of the invention, the zone 15 of visual identification of a product, the indication of a product, is indicated on its non-intended side to be contiguous to a product to be authenticated. source of information 55 on the product and the authentication codes of the label. The authentication codes comprise the sequence of alphanumeric symbols readable by the naked eye, the anti-copy mark visible to the naked eye 25, the alphanumeric character micro-writing 30, the anti-copy mark invisible to the naked eye. naked eye 40, the two-dimensional bar code 45.

During step 150 (FIG. 6), for each label is carried out: a step 155 of cutting the labels; a step 160 of capturing an image of a plurality of holograms or diffracting elements carried by said label, for example with a linear camera, and a position determining step 165 of a characteristic element of a plurality of holograms or diffracting elements carried by said label and a memory step 170 information representative of the respective positions of the characteristic elements of holograms or diffracting elements. In embodiments, during step 160, the characteristic element of each hologram or diffractive element is the center of gravity of its surface and, in the case where each hologram or diffracting element takes the form of a disk. , the center of this disc. During a step 175, the images of the tags are stored in a database.

As illustrated in FIG. 7, in a particular embodiment, for the authentication of a tag that is the subject of the present invention, a capture step 205 is first made by a communicating mobile terminal of an image. at least a portion of a tag having at least a portion of an identifier. During a step 210, the communicating mobile terminal transmits this identifier to a remote server, for example via a mobile telephone network. In embodiments, during the step 210 of transmission of the identifier, the mobile terminal transmits at least a portion of said captured image, the server determining the identifier from the image transmitted by the mobile terminal. for example by implementing optical character recognition (known as OCR for Optical Character Recognition). In other embodiments, the communicating mobile terminal performs the determination of the value of the identifier by processing at least a portion of said captured image and transmits symbols representative of the identifier thus determined.

During a step 215, the server reads, in a tag image memory, the image of a tag bearing said identifier. During a step 220, the server transmits to the communicating mobile terminal at least a portion of the image read in memory. During a step 230, the communicating mobile terminal performs the display of at least a portion of the image transmitted in superposition of an image picked up by said terminal. In embodiments, during the display step 230, at least a portion of the transmitted image is displayed in superposition of the captured image during the capture step. In embodiments, during the display step 230, at least a portion of the image transmitted is superimposed on an image captured after the step of transmitting at least a portion of the image. . In embodiments, during the display step 230, at least one of the superimposed images is a ghost image, the image resulting from the image superimposition having, at each of these points, a dependent value, both the value of a point of each of the superimposed images. In embodiments, either at the server level, when, during the step 210, the image has been transmitted, or at the communicating mobile terminal, during a step 225, an overlay is carried out automatic images. For example, we put the two images at the same scale and in the same orientation, by identifying the characteristic points of the label on the two images and overlaying them. Optionally, a deformation of one of the images is performed to take into account the difference in point of view, especially in the case where the label is not flat once it is placed. Then, one of the images is translated relative to the other so that the automatic overlay minimizes a difference between the images, point by point. Thus, the residual differences clearly appear to the user of the communicating mobile terminal and this user can quickly form an opinion on the authenticity of the product bearing the label. Thus, thanks to the database of label images, in a control phase by a user with a simple mobile phone that sends an image of the label, the server can read the two-dimensional bar code and send back on the telephone, the complete image of the label, as well as the zoom of an area comprising a portion of the random alphanumeric chain, the detail of the set of points 50, and the number of the cutting tool specific to this label, three visual information that correspond to three variable elements between the different labels. With this visual information, the user can directly verify that the label is authentic. In embodiments, the server performs, based on the image transmitted in step 235, further processing of images and codes read on that image, to determine the authenticity of the tag. In particular, during step 235, it is verified, after decoding, that the values of the sequence 20, the mark 25, the characters 30, the mark 40 and the two-dimensional bar code 45 correspond. In addition, during a step 240, the positions of the holograms or diffractive elements 35 are determined and their distances are compared at regularly spaced positions on the label with the positions stored in step 180. In function of the result of this comparison, that is to say by comparing the sum of the distances of the stored and determined positions on the basis of the received image with a predetermined limit value, it is determined whether the label is authentic and sends a message representing the authenticity of the tag at the communicating mobile terminal, during a step 245.

Claims (8)

REVENDICATIONS1. A method of manufacturing authentication tags and associating a signature with each of said tags, which comprises: - a step (110) of forming at least one hologram or diffracting element on each said tag and - for each tag: - a step (160) of capturing an image of a plurality of holograms or diffracting elements carried by said tag, - a step (165) of determining the position of a characteristic element of a plurality holograms or diffracting elements carried by said label and - a step (170) for storing information representative of the respective positions of the characteristic elements of the holograms or diffracting elements. 2. The method of claim 1, wherein the characteristic element of each hologram or diffracting element is the center of gravity of its surface. 3. Method according to one of claims 1 or 2, wherein the characteristic element of each hologram or diffracting element is the center, each said hologram or diffracting element forming a disk. 4. Method according to one of claims 1 to 3, wherein each said hologram or diffractive element is formed separately from at least one other hologram or diffracting element. 5. Device for manufacturing authentication tags and association of a signature to each of said labels, characterized in that it comprises: - means for forming at least one hologram or diffracting element on each said label; means for capturing an image of a plurality of holograms or diffracting elements carried by each said label; means for determining the position of a characteristic element of a plurality of holograms or diffracting elements carried by said label and - a means for storing information representative of the respective positions of the characteristic elements of the holograms or diffracting elements. 6. Device according to claim 5, wherein the determining means is adapted to determine the position of the center of gravity of the surface of each hologram or diffracting element. 7. Device according to one of claims 5 or 6, wherein the determining means is adapted to determine the center of each hologram or diffractive element forming a disk. 8. Device according to one of claims 5 to 7, wherein the forming means is adapted so that each said hologram or diffracting element is formed separately from at least one other hologram or diffracting element.