FR3103929A1 - METHOD AND DEVICE FOR SINGULARIZING AN OBJECT AND PROCEDURE AND DEVICE FOR AUTHENTICATION OF AN OBJECT - Google Patents

Abstract

TITLE: PROCESS AND DEVICE FOR SINGULARIZING AN OBJECT AND PROCESS AND DEVICE FOR AUTHENTICATION OF AN OBJECT A process for singling out an object, which comprises: - a step of forming the content of a representative visible electronic seal of at least one header (301), a message (302) and a signature (303), - a step of determining a shape (300) of a two-dimensional bar code having a storage capacity information divided into at least two zones (304, 305, 306), - a step of segmentation into at least two parts (301, 302, 303) of the content of the visible electronic seal according to the storage capacity of each zone , each part being assigned to a zone, - a step of recording information representative of the segmentation and of the attribution in order to recompose, on reading, the content of the visible electronic seal, - a step of encoding the seal visible electronics segmented in the shape of the two-dimensional barcode ions determined and a step of marking the object with the encoded two-dimensional barcode. Figure for abstract: figure 3

Description

METHOD AND DEVICE FOR SINGULARIZING AN OBJECT AND PROCESS AND DEVICE FOR AUTHENTICATION OF AN OBJECT

The present invention relates to a method and a device for singling out an object and a method and a device for authenticating an object. It applies, in particular, to the field of cryptography and to the detection of copies.

Visible electronic seals (acronym "CEV") are defined by a standard, their size in bytes is standardized and cannot be less than 65 bytes (16 bytes for the header, one byte for the message and 48 for Signature).

The visible electronic seals are encoded in bidirectional bar codes, preferably QR codes (registered trademark, acronym for "Quick Response" in English). However, depending on where the bidirectional barcode is to be positioned, the size of the code should be minimized, but still readable by a reader.

It is therefore not always possible to place the entire visible electronic seal in the bidirectional barcode.

The present invention aims to remedy all or part of these drawbacks.

To this end, according to a first aspect, the present invention relates to a method of singling out an object, which comprises:
- a step of forming the content of a visible electronic seal representative of at least one header, a message and a signature,
- a step of determining a shape of a two-dimensional bar code having an information storage capacity divided into at least two zones,
a step of segmentation into at least two parts of the content of the visible electronic seal according to the storage capacity of each zone, each part being allocated to a zone,
- a step of recording information representative of the segmentation and the attribution in order to recompose, on reading, the content of the visible electronic seal,
- a step of encoding the segmented visible electronic seal in the shape of the determined two-dimensional bar code and
- a step of marking the object with the encoded two-dimensional bar code.

Thanks to these provisions, the visible electronic seal is distributed over the entire two-dimensional bar code without the elements constituting the code being placed in order. The CEV is then reconstituted upon reading the code. And two-dimensional barcodes forced to be small are therefore readable while containing the entire CEV.

In embodiments, the two-dimensional bar code is a QR (trade mark, acronym for "Quick Response") code comprising at least one code reading orientation element and a payload space, at least one code reading orientation element. less one orientation element being a storage area and the payload space being another storage area.

These embodiments allow information to be carried by elements of the two-dimensional bar code that usually do not carry it.

In embodiments, the header of the visible electronic seal includes information representative of segmentation and attribution.

The advantage of these embodiments is that the cachet header can provide access to a remote resource with the information needed to re-compose the message to limit the size of the CEV.

In some embodiments, the method that is the subject of the present invention comprises:
- a step of creating a fragile anti-copying mark representative of segmentation and attribution to recompose the electronic seal and
- a step of marking the fragile anti-copy mark on the object.

These embodiments make it possible to store the CEV recomposition rules in an independent mark. It is therefore possible to perform an initial data integrity check. In particular, if the recomposed code does not match the correct code structure, the authenticity of the object is compromised.

In some embodiments, the method that is the subject of the present invention further comprises:
a step of determining a cell size of the two-dimensional bar code, the cell size being defined by an area in quantity of points,
a step of estimating a minimum quantity of points of a predetermined color in a cell so that the cell is detected as being of said color by a predetermined reader and
- for at least one cell, a step of defining an image to be represented in said cell, the quantity of points of the image of the color defining the cell being greater than the minimum estimated quantity, a set of images representing l 'header, message and / or signature.

Thanks to these provisions, the signature of the CEV is not contained in the two-dimensional bar code but represented in the cells, which saves the necessary space in the two-dimensional bar code.

In embodiments, at least a portion of the two-dimensional bar code has a high density two-dimensional bar code.

These embodiments allow the storage capacity of the two-dimensional bar code to be increased without changing its dimensions.

In embodiments, at least one orientation element has a high density two-dimensional barcode.

Thanks to these provisions, the storage capacity of the QR code is increased without affecting the capacity of this code to be read by a reader.

According to a second aspect, the present invention relates to a device for certifying an object, which comprises:
a means of forming the content of a visible electronic seal representative of at least one header, a message and a signature,
a means for determining a shape of a two-dimensional bar code having an information storage capacity divided into at least two zones,
a means of segmentation into at least two parts of the content of the visible electronic seal according to the storage capacity of each zone, each part being allocated to a zone,
a means of recording information representative of the segmentation and of the attribution in order to recompose, on reading, the content of the visible electronic seal,
- a means for encoding the segmented visible electronic seal in the shape of the determined two-dimensional bar code and
- a means of marking the object with the encoded two-dimensional bar code.

As the aims, advantages and particular characteristics of the singularization device that is the subject of the present invention are similar to those of the singularization method that is the subject of the present invention, they are not recalled here.

According to a third aspect, the present invention relates to a method for authenticating an object, which comprises:
a step of reading a two-dimensional bar code obtained according to the singularization method which is the subject of the present invention,
- a step of accessing information representative of the segmentation and attribution in order to recompose the content of a visible electronic seal,
- a step of recomposing the content of the visible electronic seal according to the information accessed and
- a step of verifying the authenticity of the reconstructed visible electronic seal content.

Thanks to these provisions, the authenticity of the CEV can be verified, if the recomposition corresponds to the structure of a CEV, even if the code is distributed over several elements of the two-dimensional bar code.

According to a fourth aspect, the present invention relates to a device for authenticating an object, which comprises:
a means for reading a two-dimensional bar code obtained according to the singularization method which is the subject of the present invention,
- a means of access to information representative of the segmentation and of the attribution in order to recompose the content of a visible electronic seal,
- a means of recomposing the content of the visible electronic seal according to the information accessed and
- a means of verifying the authenticity of the content of the reconstructed visible electronic seal.

The aims, advantages and particular characteristics of the authentication method object of the present invention being similar to those of the authentication device object of the present invention, they are not repeated here.

The various aspects and particular characteristics of the present invention are intended to be combined with one another so that a marking of an object produced according to one of the first two aspects allows the authentication of this object according to one of the last two aspects. .

Other advantages, aims and particular characteristics of the invention will emerge from the nonlimiting description which follows of at least one particular embodiment of the method and of the device for singling out an object and of the method and of the authentication device. an object of the present invention, with reference to the accompanying drawings, in which:

represents, schematically and in the form of a flowchart, a particular succession of steps of the singularization process which is the subject of the present invention,

schematically represents a first particular embodiment of a singularization device which is the subject of the present invention,

represents, schematically, a first embodiment of an object singled out by a method which is the subject of the present invention

represents, schematically, a second embodiment of an object singled out by a method which is the subject of the present invention and

represents, schematically and in the form of a flowchart, a particular succession of steps of the authentication method which is the subject of the present invention and

schematically represents a first particular embodiment of an authentication device which is the subject of the present invention.

This description is given without limitation, each characteristic of an embodiment being able to be combined with any other characteristic of any other embodiment in an advantageous manner.

We now note that the figures are not to scale.

We call:
- Object: any concrete thing, perceptible by sight, touch, for example an electronic chip or a document on which information is marked.
- Point: the smallest element to mark an object, for example a pixel.
- Cell: a set of points defined by at least two dimensions in number of points.
- Two-dimensional bar code: a two-dimensional graphic code comprising cells, for example square, each cell being at least one color from two distinct colors, examples of two-dimensional bar codes are QR codes ( registered trademark, acronym for "Quick Response" in English) or even datamatrix, semacodes (registered trademark).
- Marking: affixing a digital graphic element to an object, for example by engraving or printing.
- Fragile anti-copy mark: mark whose degradation by noise during marking, that is to say the generation of point errors, individually unpredictable, causing a point to be interpreted with an incorrect value, then copied, can be measured to discriminate an original from a copy.
- Visible electronic seal (acronym "CEV"): set of data structured in the form of a machine-readable code containing a header, a message and their signature by the sender. The header determines the type of message and the sender. The header references a signing certificate. An optional auxiliary data block can be added after signing.
- Signature: a certificate defines the digital signature algorithm used and incidentally the size of the signature, which is usually based on the expected lifetime of the signature. The signature is used to verify the integrity of the signed data and to identify / authenticate the issuer of the object. In the context of a CEV, the certification is defined in the header and the signature is used to verify the integrity of the header and of the message.

There is seen in Figure 1, which is not to scale, a schematic view of an embodiment of the method 10 of singling out an object, object of the present invention.

The method 10 of singling out an object comprises:
a step 101 of forming the content of a visible electronic seal representative of at least one header, a message and a signature,
a step 102 of determining a shape of a two-dimensional bar code having an information storage capacity distributed over at least two zones,
a step of segmentation 103 into at least two parts of the content of the visible electronic seal as a function of the storage capacity of each zone, each part being allocated to a zone,
- a recording step 107 of information representative of the segmentation and of the attribution in order to recompose, on reading, the content of the visible electronic seal,
- an encoding step 108 of the visible electronic seal segmented in the shape of the determined two-dimensional bar code and
a step 109 of marking the object with the encoded two-dimensional bar code.

During the step of forming 101 a content of a visible electronic seal, the content of the visible electronic seal is formed from certification information contained in the header of the visible electronic seal, a message and a digital signature process. The digital signature process can be specified in a manifesto. Access to a resource including the manifesto is preferably encoded in the header.

The content of the visible electronic seal is adapted to be encoded in a two-dimensional bar code, also known as a “visible electronic seal”.

During the determination step 102, the determined shape has:
- dimensions in number of cells and / or in number of points and / or in dimensions of the metric system,
- an information storage capacity divided into at least two areas,
- optionally, graphic elements defined by a standard.

In embodiments, the two-dimensional bar code may be a QR code (acronym for "Quick Response") comprising at least one code reading orientation element and a payload space, at least one orientation element being a storage area and the payload space being another storage area. A code reading orientation element is a black square, with another black square on a white background in its center. Of course, the colors of the orientation element can be adapted depending on the colors used to represent the barcode in two dimensions. The payload space is directly related to the dimensions of the two-dimensional barcode and the cells that make up the code.

In embodiments, the two-dimensional bar code may be a datamatrix (trademark) code having at least one code reading orientation element and a payload space, at least one orientation element being a storage area and payload space being another storage area. The orientation element has two adjacent solid-colored, for example black, borders. For a rectangular or square datamatrix, the borders form a corner.

In preferred embodiments, at least part of the two-dimensional bar code has a high density two-dimensional bar code. For example, the two-dimensional barcode can be a QR code whose center is replaced by a datamatrix. The payload space will therefore be reduced but a new storage area, the datamatrix, with a storage capacity greater than the deleted payload space is created. In another preferred example, the two-dimensional bar code can be a QR code, a code reading orientation element of which is replaced by a datamatrix. The storage space in the orientation element is therefore greatly increased.

In preferred embodiments, the method 10 comprises:
a step 104 for determining a cell size of the two-dimensional bar code, the cell size being defined by an area in quantity of points,
a step 105 of estimating a minimum quantity of points of a predetermined color in a cell so that the cell is detected as being of said color by a predetermined reader and
- for at least one cell, a step of defining 106 an image to be represented in said cell, the quantity of points of the image of the color defining the cell being greater than the minimum estimated quantity, a set of images representing header, message and / or signature.

These embodiments allow the contents of the cells to be used as a storage area.

The minimum and maximum dimensions of a two-dimensional barcode depend on:
- the area allocated on the object to place the two-dimensional bar code, defining a maximum dimension of the two-dimensional bar code and
- the amount of information to be encoded in the two-dimensional bar code influencing a minimum dimension of the two-dimensional bar code.

The area allocated to the object is chosen by the operator affixing the two-dimensional bar code to the object. This operator is the object's manufacturer or its distributor, for example.

The number of colors in the two-dimensional barcode can influence the amount of information that can be encoded in a two-dimensional barcode.

Two-dimensional bar codes, in order to be able to be read by a predetermined reader, must have cells whose minimum dimensions are specified in the various norms and standards defining these codes.

Thus, depending on the surface area allocated to the object and the amount of information to be encoded, minimum cell dimensions and therefore the minimum and maximum dimensions of a two-dimensional bar code can be determined.

In other words, the maximum size of the cells can be determined based on the dimensions of the two-dimensional barcode (which depend on the allocated area) and the amount of information to be encoded.

Furthermore, depending on the marking resolution, dimensions expressed in centimeters or millimeters, for example, are expressed in number of dots, for example in dots per inch (acronym "DPI" or PPP ").

In the determination step 104, the size of the cells is calculated based on at least the marking resolution, the surface area allocated to the object and the amount of information to be encoded.

Once the quantity of cells has been determined, the minimum quantity of dots of a predetermined color in a cell for the cell to be detected as being of said color by a predetermined reader is estimated 105.

The predetermined color is one of the colors used in a two-dimensional barcode. Generally, two-dimensional bar codes have two colors, preferably black and white. In embodiments, the two-dimensional bar codes have three or more colors.

For the remainder of the description, the general case of two colors, black and white, is chosen to illustrate the invention. The following description can, of course, be adapted to the case of at least three colors or different colors.

At a minimum, for a color to be detected correctly by the reader, the cell must have strictly more than 50% of dots of said color. For example, for a cell size of 10 dots by 10 dots, at least 51 dots must be black for the cell to be detected as black.

Now, it is known to those skilled in the art that the marking step and the reading step cause random errors, the rate of which is determinable and predictable.

In the estimation step 105, the marking and reading error rate, by the predetermined reader, is calculated, measured, or estimated. And the minimum amount of dots of a predetermined color is estimated to predict said obtained error rate.

Then, for at least one cell, the method 10 comprises a step of defining 106 an image to be represented in said cell, the quantity of points of the image of the color defining the cell being greater than the minimum estimated quantity. During the definition step 106, the image can be selected from a database of images respecting the constraint concerning the quantity of points of the image of the color defining the cell and the maximum number of colors of the code to be two-dimensional bars.

Preferably, the image represents an alphanumeric character. For example, the dots of the color whose quantity is greater than the estimated minimum quantity represent an alphanumeric character. For example, in a box that should be read as black, the black dots represent the alphanumeric character.

In other embodiments, the dots other than the dots of the color whose amount is greater than the estimated minimum amount represent an alphanumeric character. For example, in a box that should be read as white, the black dots represent the alphanumeric character.

In some embodiments, only part of the set of alphanumeric characters may be represented in an image. That is, some characters are considered too close to another character to be represented. Examples of such characters are "O" and "Q" or alternatively "P" and "R". Only one of the two characters may be represented on the same two-dimensional bar code. This information can be entered in a remote resource.

In some embodiments, the alphanumeric characters shown may be in upper or lower case.

Preferably, the characters refer to an element of the message, for example the signature.

During the determination step 102, storage areas each having a storage capacity are determined. According to the embodiments expressed above, the storage areas can be, for example:
- a payload space of a two-dimensional barcode,
- an orientation element of a two-dimensional bar code,
- a datamatrix embedded in a two-dimensional barcode or
- the cell content of a two-dimensional bar code.

The method 10 comprises a step of segmentation 103 into at least two parts of the content of the visible electronic seal as a function of the storage capacity of each zone, each part being allocated to a zone.

The segmentation 103 depends on the storage capacity of each zone. Preferably, each element among the header, the message, the signature or a secondary information field is kept in a part. In some embodiments, during the segmentation step 103, the area allocated to each part of the content of the CEV has sufficient capacity to store redundancies of the stored part.

The segmentation 103 of the content of CEV and the attribution of each part to a zone are recorded during the recording step 107 of information representative of the segmentation and the attribution in order to recompose, on reading, the stamp. visible electronics.

Preferably, the header of the visible electronic seal includes information representative of the segmentation and attribution. For example, segmentation and attribution 103 is recorded on a remote resource referred to in the header, such as a website of the certification authority or the manufacturer. Or, the representative information may be a manifest whose location is obtained from the information contained in the header.

In other embodiments, method 10 includes:
- a step of creation 110 of a fragile anti-copying mark representative of the segmentation and the attribution to recompose the electronic seal and
a step of marking 111 of the fragile anti-copying mark on the object.

For example, information representative of segmentation and attribution is encoded in a fragile anti-copy mark. In these embodiments, the generated code includes redundancies configured so that the information is readable and / or can be reconstructed, despite the degradations of the fragile anti-copy mark due to printing. Thus, the anti-copy mark is very fragile but the information can be considered as robust, that is to say that it is possible to access its content.

In some embodiments, an element representative of the signature produced and redundancies are encoded in the fragile anti-copy mark. These embodiments make it possible to verify the authenticity of the signature at the time of marking even if the signing certificate is no longer accessible.

In some embodiments, a message encoded in the fragile anti-copy mark includes at least one piece of information representative of the object to which the mark is to be affixed. Information representative of the object can be any information relating to the manufacture and / or distribution of the product. For example, a manufacturer's identification or serial number, or an authorized distributor's identification, a physical property taken from a photograph of the object, or an artefact metric.

An artifact metric is a unique fingerprint corresponding to the object. Artifact metrics are calculated from individual formation marks at each object during the manufacture of the object. These are, in a way, fingerprints of the object. Artifact metrics can be calculated from an image of the object.

The step of marking 111 of the fragile anti-copy mark is carried out by any means known to those skilled in the art, for example, a printer or a laser for engraving the object.

The encoding step 108 can be carried out by means known to those skilled in the art, for example by means of a symmetric key or an asymmetric key, scrambling and permutations, in a manner known to those skilled in the art. job.

The two-dimensional barcode is then marked 109 on the object. The marking step 109 is carried out by any means known to those skilled in the art, for example, a printer or a laser for engraving the object. Preferably, the step of marking 111 of the fragile anti-copy mask on the object is carried out simultaneously with the step of marking 109 of the bar code in two dimensions and with the same means.

FIG. 2 represents a first particular embodiment of a singularization device 20 which is the subject of the present invention.

The device 20 for singling out an object comprises:
a means 201 for forming the content of a visible electronic seal representative of at least one header, a message and a signature,
a means 202 for determining a shape of a two-dimensional bar code having an information storage capacity distributed over at least two zones,
a means of segmentation 203 into at least two parts of the content of the visible electronic seal according to the storage capacity of each zone, each part being allocated to a zone,
a recording means 204 of information representative of the segmentation and of the attribution in order to recompose, on reading, the content of the visible electronic seal,
- a means 205 for encoding the visible electronic seal segmented in the shape of the determined two-dimensional bar code and
a means 206 for marking the object with the encoded two-dimensional bar code.

Preferably, the embodiments of the device 20 are configured to implement the steps of the method 10 and their embodiments as explained above and the method 10 as well as its various embodiments can be implemented by the embodiments of the device 20.

The training 201, determination 202, segmentation 203, recording 204 and encoding 205 means are preferably a microcontroller implementing a computer program.

The marking means 206 can be any means known to those skilled in the art, such as a printer or a laser for engraving the object.

FIG. 3 shows a particular embodiment of a two-dimensional bar code obtained by a method that is the subject of the present invention.

Figure 3 shows content of a CEV, comprising a header 301, a message 302 and a signature 303.

A two-dimensional barcode form 300 has three storage areas: an orientation element 304, a payload space 305, and the contents of cells 306. The contents of cell 306 are represented by a letter "B". in upper case, in black on a white background, replacing a white cell.

The two-dimensional barcode shape 300 is a QR code.

In Figure 3, the content of the header is encoded in the orientation element 304, the message 302 is encoded in the payload space 305 and the signature, which does not need to be. secret, is encoded in the contents of cells 306.

FIG. 4 shows a particular embodiment of a two-dimensional bar code obtained by a method that is the subject of the present invention.

Figure 4 shows content of a CEV, comprising a header 301, a message 302 and a signature 303.

A two-dimensional barcode form 300 has three storage areas: an orientation element 402, replaced by a datamatrix, a payload space 401, and the content of cells 403. The content of cell 403 is represented by a letter "B" in upper case, in black on a white background, replacing a white cell.

The two-dimensional barcode shape is a QR code.

In Figure 4, the message 302 is encoded in the datamatrix in the orientation element 402, the header 301 is encoded in the payload space 401 and the signature, which does not need to be be secret, is encoded in the contents of cells 403.

Also observed in Figure 4, a fragile anti-copy mark 404 which encodes an element representative of the signature. The fragile anti-copy mark 404 is a sealvector (registered trademark) for example. In embodiments, the fragile anti-copy mark 404 encodes an element representative of the subject matter and / or attribution segmentation information.

FIG. 5 is a schematic view of one embodiment of the authentication method 50 which is the subject of the present invention.

The authentication method 50 of an object comprises:
a step of reading 501 of a two-dimensional bar code obtained according to the method according to singularization which is the subject of the present invention,
a step 502 for accessing information representative of the segmentation and the attribution in order to recompose a content of a visible electronic seal,
- a step of recomposition 503 of the content of the visible electronic seal as a function of the information accessed and
a step 504 for verifying the authenticity of the content of the reconstructed visible electronic seal.

During the reading step 501, the two-dimensional bar code is decoded by a reader 501. The reader 501 is, for example, a communicating portable terminal provided with a camera or a camera which scans the code. . The communicating portable terminal then applies a code decoding algorithm. The reader accesses 502 information representative of segmentation and attribution to recompose the content of the CEV. For example, the reader accesses 502 a remote resource, such as a secure server indicating which segment is in which zone.

In embodiments, alphanumeric characters are represented in cells of the two-dimensional bar code without changing the color detected by a reader of the two-dimensional bar code. That is, a minimum amount of dots of a predetermined color in a cell for the cell to be detected as being of that color by a predetermined reader is observed when representing the alphanumeric character.

Preferably, the alphanumeric characters represent the signature and can be read by optical character recognition.

In reading step 501, a fragile anti-copy mark can be performed read with the same reader as the reader reading the two-dimensional bar code. In reading step 501, the original or copied character of the fragile anti-copy mark is evaluated. The evaluation of the original or copied character depends on an error rate detected when reading the fragile anti-copy mark. The error rate is compared to a predetermined limit value which determines whether the fragile anti-copy mark is an original or not.

Indeed, the printed fragile anti-copy mark presents, from its first impression on the document, a significant quantity of random errors which require that a copy, made with the same printing means as the original document, of the image of the document. The printed identification has even more errors, with the total number of errors in the copy making it possible to detect that it is a copy. The redundancies make it possible to correct printing and / or reading defects and wear or erasure marks of the fragile anti-copy mark.

The copied nature of the fragile anti-copy mark is a first level of verification of the authenticity of the object. During the step of verifying the authenticity of the object 504, the copied character of the fragile anti-copy mark is preferably indicated to a user.

During redial 503, the contents of each zone are juxtaposed in the order defined by the information accessed. The content of the CEV is therefore recomposed and its authenticity can be verified 504 in a manner known to those skilled in the art.

Preferably, during the verification step 504, the content of a fragile anti-copy mark read represents an element representative of the signature. In the verification step, a comparison of the representative element read in the fragile anti-copy mark and the signature read in the two-dimensional bar code is made to determine the authenticity of the signature at the time of marking.

In some embodiments, during the step of reading a fragile anti-copying mark, information representative of the object on which the mark has been affixed is obtained, the method further comprising a step of comparing the representative information obtained and object.

Representative information can be a serial number, for example. The serial number of the object can be obtained by optical character recognition. In these cases, the comparison step can be performed by comparing character by character. Depending on the result of the comparison, information on the authenticity of the two-dimensional bar code and / or the fragile anti-copy mark may be indicated to the user during the verification step 504.

FIG. 6 shows a particular embodiment of a device 60 for authenticating an object, which is the subject of the present invention, which comprises:
a means 601 for reading a two-dimensional bar code obtained according to the singularization method which is the subject of the present invention,
a means of access 602 to information representative of the segmentation and of the attribution in order to recompose a content of a visible electronic seal,
- a means of recomposition 603 of the content of the visible electronic seal according to the information accessed and
- A verification means 604 of the authenticity of the reconstructed visible electronic seal content.

The means of access 602, redial 603 and verification 604 are preferably a microcontroller implementing a computer program.

The reading means 601 can be any means known to those skilled in the art, such as a communicating portable terminal provided with a camera or a camera which scans the code. The communicating portable terminal then applies a code decoding algorithm.

Preferably, the embodiments of the device 60 are configured to implement the steps of the method 50 and their embodiments as explained above and the method 50 as well as its various embodiments can be implemented by the embodiments of the device 60.

Claims (10)

Method (10) of singularization of an object, characterized in that it comprises:
- a step of forming (101) the content of a visible electronic seal representative of at least one header, a message and a signature,
- a step of determining (102) a shape of a two-dimensional bar code having an information storage capacity divided into at least two zones,
- a step of segmentation (103) into at least two parts of the content of the visible electronic seal according to the storage capacity of each zone, each part being allocated to a zone,
- a recording step (107) of information representative of the segmentation and of the attribution in order to recompose, on reading, the content of the visible electronic seal,
- a step of encoding (108) the visible electronic seal segmented in the shape of the determined two-dimensional bar code and
- a marking step (109) of the object with the encoded two-dimensional bar code. A method according to claim 1, wherein the two-dimensional bar code is a QR (trade mark, acronym for "Quick Response") code comprising at least one code reading orientation element and a payload space. , at least one orientation element being a storage area and the payload space being another storage area. A method according to either of claims 1 or 2, wherein the header of the visible electronic seal includes information representative of segmentation and attribution. Method according to one of claims 1 to 3, which comprises:
- a step of creation (110) of a fragile anti-copying mark representative of the segmentation and of the attribution in order to recompose the electronic seal and
- A marking step (111) of the fragile anti-copy mark on the object. Method according to one of claims 1 to 4, which further comprises:
- a step of determining (104) a cell size of the two-dimensional bar code, the cell size being defined by an area in quantity of points,
- a step of estimating (105) a minimum quantity of dots of a predetermined color in a cell so that the cell is detected as being of said color by a predetermined reader and
- for at least one cell, a step of defining (106) an image to be represented in said cell, the quantity of points of the image of the color defining the cell being greater than the estimated minimum quantity, a set of images representing the header, message and / or signature. A method according to one of claims 1 to 5, wherein at least part of the two-dimensional bar code has a high density two-dimensional bar code. A method according to claims 2 and 6, wherein at least one orientation element has a high density two-dimensional bar code. Device (20) for certifying an object, characterized in that it comprises:
- a means of forming (201) the content of a visible electronic seal representative of at least one header, a message and a signature,
- means for determining (202) a shape of a two-dimensional bar code having an information storage capacity distributed in at least two zones,
- a means of segmentation (203) into at least two parts of the content of the visible electronic seal according to the storage capacity of each zone, each part being allocated to a zone,
- a recording means (204) of information representative of the segmentation and of the attribution in order to recompose, on reading, the content of the visible electronic seal,
- encoding means (205) of the segmented visible electronic seal in the shape of the determined two-dimensional bar code and
- a means of marking (206) of the object with the encoded two-dimensional bar code. Method (50) for authenticating an object, characterized in that it comprises:
- a reading step (501) of a two-dimensional bar code obtained according to the method according to one of claims 1 to 7,
- a step of access (502) to information representative of the segmentation and of the attribution in order to recompose a content of the visible electronic seal,
- a step of recomposition (503) of the content of the visible electronic seal according to the information accessed and
- a verification step (504) of the authenticity of the reconstructed visible electronic seal. Device (60) for authenticating an object, characterized in that it comprises:
- means (601) for reading a two-dimensional bar code obtained according to the method according to one of claims 1 to 7,
- a means of access (602) to information representative of the segmentation and of the attribution in order to recompose a content of a visible electronic seal,
- a recomposition means (603) of the content of the visible electronic seal according to the information accessed and
- A means of verification (604) of the authenticity of the reconstructed visible electronic seal.